Saudi Arabians woke up over the weekend to a once-in-a-decade cabinet reshuffle. Octogenarian oil minister Ali al-Naimi, who has been in charge of the Kingdom’s energy policy since 1995, was replaced by Khaled al-Falih, who is to head the newly created Energy, Industry, and Natural Resources Ministry. Majed al-Qusaibi was named head of the newly created Commerce and Investment Ministry. Finally, Ahmed al-Kholifey was made governor of the Saudi Arabia’s Central Bank (SAMA). It may come as a surprise to many Saudis that the origin of this reshuffle—and indeed the Kingdom’s new economic direction—finds its impetus in a report by the global management consulting firm McKinsey & Company.

A man with a plan

Saudi Arabia has been struggling to deal with the impact of lower oil prices. After years of recording budget surpluses, the government has seen its budgetary deficit grow to 15 percent of GDP. Lower oil prices—coupled with tensions with regional rival Iran over Yemen, Syria, and Lebanon—have put the Kingdom’s finances under pressure. Since oil prices began to plummet, Saudi Arabia’s ever-ambitious Deputy Crown Prince Mohammed bin Salman has been spearheading an ambitious reform initiative that seeks to diversify the Kingdom’s economy away from oil. 

Dubbed “Saudi Arabia’s Vision 2030,” the prince says that the new economic blueprint will increase the role of the private sector from 40 percent to 60 percent, reduce unemployment from 11 percent to 7.6 percent, and grow non-oil income exponentially. This is to be financed by the partial privatization of the Kingdom’s oil behemoth, Aramco. 

The 2030 document outlines a number of significant reforms that seek to change not only the Saudi economy, but state-society relations more broadly, in a way that has been done since the Kingdom’s founding.

The 2030 document outlines a number of significant reforms that seek to change not only the Saudi economy, but state-society relations more broadly, in a way that hasn't been done since the Kingdom’s founding. The prince’s vision seems to have been inspired by a report issued by the McKinsey Global Institute in December 2015 titled “Moving Saudi Arabia’s Economy Beyond Oil.” The vision and the report have similar policy prescriptions for diversifying the Kingdom’s economy away from oil. 

Such similarities highlight the influence of consultancies on policymaking in the Kingdom. Indeed, Bloomberg news reported that consultancies are set to earn 12 percent more in commissions in Saudi Arabia this year, the fastest growth amongst the world’s advisory markets. In a wide-ranging interview with The Economist in January, Prince Mohammed himself said that “McKinsey participates with us in many studies.” According to the Financial Times, Saudi businessmen have sarcastically dubbed the Ministry of Planning as the “McKinsey Ministry.”

McKinsey’s key report, full with glossy illustrations, contains consultant buzzwords (“transformation,” “efficiency,” and “synergies”) that would make Marty Kaan in Showtimes’s House of Lies proud. It’s by no means novel for consultants to advise governments in the region and across the world, and indeed the report does outline an ambitious blueprint for the Kingdom’s economic transformation and diversification away from oil. 

Will the public buy it?

But in a glaring omission, the report does not adequately explain how the Saudi government will be able to change the mindset of everyday Saudi Arabia citizens, who have long been accustomed to state largesse that included fuel subsidies, loans, free land, and public sector jobs. 

This is the key issue. The reform plans sound promising, and will indeed make headway in weaning the Kingdom off its oil “addiction” (as the prince himself put it). But how will everyday citizens react to the reforms? The Saudi government will be asking more of its citizens—will the citizens in turn ask for more accountability and representation? Since January, the prices of gasoline, electricity, and water have gone up. There was a public outcry against higher utility prices, which lead King Salman to fire the water minister to absorb the public’s anger. 

Such discontent is the harbinger of things to come. The coming months and years will show how Saudi leadership implements much needed economic reforms without alienating its population. While the outcome is uncertain, one thing is: consultants will continue to flock to Saudi Arabia to work on the “mother of all transformation projects.”

Editors' Note: This post was corrected on May 12, 2016 to clarify that the report “Moving Saudi Arabia’s Economy Beyond Oil” was issued by the McKinsey Global Institute, the research arm of McKinsey & Company. MGI’s work is independent and wholly funded by McKinsey Partners. The MGI report was not commissioned by the government of Saudi Arabia and has no formal role in government decision-making.

“If the Americans and their regional allies want to pass through the Strait of Hormuz and threaten us, we will not allow any entry,” said deputy commander of Iran’s Revolutionary Guards, Hossein Salami, last Wednesday. Iran has a long history of making threats against this critical waterway, through which some 17 million barrels of oil exports pass daily, though it has not carried them out. But multiple regional security threats highlight threats to energy transit from and through the Middle East and North Africa (MENA)—and demand new thinking about solutions.

Weak spots

Hormuz attracts attention because of its evident vulnerability. But recent years have seen severe disruptions to energy flows across the region: port blockades in Libya; pipeline sabotage in Egypt’s Sinai, Yemen, Baluchistan in Pakistan, and Turkey’s southeast; attacks on oil and gas installations across Syria and Iraq; piracy off Somalia. Energy security is threatened at all scales, from local community disturbances and strikes, up to major regional military confrontations.

Of course, it would be best to mitigate these energy security vulnerabilities by tackling the root causes of conflict across the region. But while disruption and violence persist, energy exporters and consumers alike should guard against complacency.

A glut of oil and gas supplies globally—with low prices, growing U.S. self-sufficiency, and the conclusion of the Iranian nuclear deal—may seem to have reduced the urgency: markets have hardly responded to recent flare-ups. But major economies – even the United States – still remain dependent, directly or indirectly, on energy supplies from the MENA region. Spare oil production capacity is at unusually low levels, leaving the balance vulnerable to even a moderate interruption.

Most concern has focused on oil exports, given their importance to the world economy. But the security of liquefied natural gas (LNG) shipments is an under-appreciated risk, particularly for countries such as Japan and South Korea which are heavily dependent on LNG. A disruption would also have severe consequences for countries in the Middle East and North Africa, depriving them not only of revenues but potentially of critical imports.

Doing better 

There are three broad groups of approaches to mitigating the risk of energy transit disruptions: infrastructure, institutions, and market. 

1. Infrastructure includes the construction of bypass pipelines avoiding key choke-points and strategic storage.
   
   Existing bypass pipelines include SUMED (which avoids the Suez Canal); the Habshan-Fujairah pipeline in the UAE (bypassing Hormuz); and the Saudi Petroline, which runs to the Red Sea, hence offering an alternative to the Gulf and Hormuz. Proposed projects include a link from other Gulf Cooperation Council (GCC) countries to Oman’s planned oil terminal at Duqm on the Indian Ocean; new or rehabilitated pipelines from Iraq across Jordan and Turkey; an expansion of Petroline; and a new terminal in southern Iran at Jask.
   
   Strategic storage can be held by oil exporters, by importers, or a combination (in which exporters hold oil close to their customers’ territory, as with arrangements between Saudi Arabia and Japan, and between Abu Dhabi and Japan and India).


2. Institutional approaches include mechanisms to deal with disruptions, such as cooperative sharing arrangements.
   
   More analysis has focused on infrastructure than on institutional and market mitigation. Yet these approaches have to work together. Physical infrastructure is not enough: it has to be embedded in a suitable framework of regulation, legislation, and diplomacy. Cross-border or multilateral pipelines require agreements on international cooperation; strategic storage is most effective when rules for its use are clear, and when holders of storage agree not to hoard scarce supplies. 
   
   The effective combination of infrastructure and institutions has a strategic benefit even if it is never used. By making oil exporters and consumers less vulnerable to threats, it makes it less likely that such threats will be carried out.
   
   Alliances can be useful for mutual security and coordination. However, they raise the difficult question of whom they are directed against. Mutually-hostile alliances would be a threat to regional energy security rather than a guarantor. Organizations such as the International Energy Agency (IEA), the International Energy Forum (IEF), Organization of Petroleum Exporting Countries (OPEC), Gulf Cooperation Council, and the Association of Southeast Asian Nations (ASEAN) could all have roles, but none is ideally placed. Rather than creating another organization, reaching an understanding between existing bodies may be more effective.


3. In general, markets cope well with the task of allocating scarce supplies. Better and timelier data, such as that gathered by the IEF, can greatly improve the functioning of markets. Governments do have a role in protecting the most vulnerable consumers and ensuring sufficient energy for critical services, but price controls, rationing, and export bans have usually been counterproductive, and many of the worst consequences of so-called energy crises have come from well-meaning government interference with the normal market process of adjustment.
   
   However, it is generally difficult or impossible for a single company or country to capture all the benefits of building strategic infrastructure—which, as with a bypass pipeline, may only be required for a few months over a period of decades. International financing, perhaps backed by a major energy importer—mostly likely China—can help support such projects, particularly at a time of fiscal austerity in the Middle East.

Energy exporters within the MENA region may often find their interests divergent. But the field of energy security is one area for more fruitful cooperation—at least between groups of states, and some external players, particularly their increasingly important Asian customers. If regional tensions and conflicts cannot be easily solved, such action at least alleviates one of the serious risks of the region’s turmoil.

For more on this topic, read Robin Mills’ new analysis paper “Risky routes: Energy transit in the Middle East.”

Rooftop solar is booming in U.S. cities.

One of the most exciting infrastructure developments within metropolitan America, the installation of over a million solar photovoltaic (PV) systems in recent years, represents nothing less than a breakthrough for urban sustainability — and the climate.

Prices for solar panels have fallen dramatically. Residential solar installations surged by 66 percent between 2014 and 2015 helping to ensure that solar accounted for 30 percent of all new U.S. electric generating capacity. And for that matter, recent analyses conclude that the cost of residential solar is often comparable to the average price of power on the utility grid, a threshold known as grid parity.

So, what’s not to like? Rooftop solar is a total winner, right?

Well, not quite: The spread of rooftop solar has raised tricky issues for utilities and the public utilities commissions (PUCs) that regulate them. 

Specifically, the proliferation of rooftop solar installations is challenging the traditional utility business model by altering the relationship of household and utility—and not just by reducing electricity sales. In this respect, the solar boom has prompted significant debates in states like New York and California about the best rates and policies to ensure that state utility rules and rates provide a way for distributed solar to flourish even as utilities are rewarded for meeting customer demands. Increasingly, this ferment is leading to thoughtful dialogues aimed at devising new forms of policy and rate design that can—as in New York—encourage distributed energy resources (DERs) while allowing for distribution utilities to adapt to the new era.

However, in some states, the ferment has prompted a cruder set of backlashes. Most pointedly, some utilities contend that the “net-metering” fees paid to homeowners with rooftop installations for excess solar power they send back to the grid unfairly transfer costs to the utilities and their non-solar customers.

And so in a number of states, utility interests have sought to persuade state regulators to roll back net-metering provisions, arguing they are a net cost to the overall electricity system.  Most glaringly, the local utility in Nevada successfully wielded the cost-shift theory last winter to get the Nevada Public Utilities Commission to drastically curtail the state’s net-metering payments, prompting Solar City, Sunrun, and Vivint Solar—the state’s three largest providers of rooftop panels—to leave the Nevada market entirely. The result: New residential solar installation permits plunged 92 percent in Nevada in the first quarter of 2016.

All of which highlights a burning question for the present and future of rooftop solar: Does net metering really represent a net cost shift from solar-owning households to others? Or does it in fact contribute net benefits to the grid, utilities, and other ratepayer groups when all costs and benefits are factored in? As to the answer, it’s getting clearer (even if it’s not unanimous). Net metering — contra the Nevada decision — frequently benefits all ratepayers when all costs and benefits are accounted for, which is a finding state public utility commissions, or PUCs, need to take seriously as the fight over net metering rages in states like Arizona, California, and Nevada.  Regulators everywhere need to put in place processes that fairly consider the full range of benefits (as well as costs) of net metering as well as other policies as they set and update the policies, regulations, and tariffs that will play a critical role in determining the extent to which the distributed solar industry continues to grow.

Fortunately, such cost-benefit analyses have become an important feature of state rate-setting processes and offer important guidance to states like Nevada.  So what does the accumulating national literature on costs and benefits of net metering say?  Increasingly it concludes— whether conducted by PUCs, national labs, or academics — that the economic benefits of net metering actually outweigh the costs and impose no significant cost increase for non-solar customers.  Far from a net cost, net metering is in most cases a net benefit—for the utility and for non-solar rate-payers.

Of course, there are legitimate cost-recovery issues associated with net metering, and they vary from market to market. Moreover, getting to a good rate design, which is essential for both utility revenues and the growth of distributed generation, is undeniably complicated.  If rates go too far in the direction of “volumetric energy charges”—charging customers based on energy use—utilities could have trouble recovering costs when distributed energy sources reach higher levels of penetration. On the other hand, if rates lean more towards fixed charges—not dependent on usage—it may reduce incentives for customers to consider solar and other distributed generation technologies.  

Moreover, cost-benefit assessments can vary due to differences in valuation approach and methodology, leading to inconsistent outcomes. For instance, a Louisiana Public Utility Commission study last year found that that state’s net-metering customers do not pay the full cost of service and are subsidized by other ratepayers. How that squares with other states’ analyses is hard to parse.

Nevertheless, by the end of 2015, regulators in at least 10 states had conducted studies to develop methodologies to value distributed generation and net metering, while other states conducted less formal inquiries, ranging from direct rate design or net-metering policy changes to general education of decisionmakers and the public. And there is a degree of consensus.  What do the commission-sponsored analyses show? A growing number show that net metering benefits all utility customers:

• In 2013 Vermont’s Public Service Department conducted a study that concluded that “net-metered systems do not impose a significant net cost to ratepayers who are not net-metering participants.” The legislatively mandated analysis deemed the policy a successful component of the state’s overall energy strategy that is cost effectively advancing Vermont’s renewable energy goals.

• In 2014 a study commissioned by the Nevada Public Utility Commission itself concluded that net metering provided $36 million in benefits to all NV Energy customers, confirming that solar energy can provide cost savings for both solar and non-solar customers alike. What’s more, solar installations will make fewer costly grid upgrades necessary, leading to additional savings. The study estimated a net benefit of $166 million over the lifetime of solar systems installed through 2016. Furthermore, due to changes to utility incentives and net-metering policies in Nevada starting in 2014, solar customers would not be significantly shifting costs to other ratepayers.

• A 2014 study commissioned by the Mississippi Public Services Commission concluded that the benefits of implementing net metering for solar PV in Mississippi outweigh the costs in all but one scenario. The study found that distributed solar can help avoid significant infrastructure investments, take pressure off the state's oil and gas generation at peak demand times, and lower rates. (However, the study also warned that increased penetrations of distributed solar could lead to lower revenues for utilities and suggested that the state investigate Value of Solar Tariffs, or VOST, and other alternative valuations to calculate the true cost of solar.)

• In 2014 Minnesota’s Public Utility Commission approved a first-ever statewide “value of solar” methodology which affirmed that distributed solar generation is worth more than its retail price and concluded that net metering undervalues rooftop solar. The “value of solar” methodology is designed to capture the societal value of PV-generated electricity. The PUC found that the value of solar was at 14.5 cents per kilowatt hour (kWh)—which was 3 to 3.5 cents more per kilowatt than Xcel's retail rates—when other metrics such as the social cost of carbon, the avoided construction of new power stations, and the displacement of more expensive power sources were factored in.

• Another study commissioned by the Maine Public Utility Commission in 2015 put a value of $0.33 per kWh on energy generated by distributed solar, compared to the average retail price of $0.13 per kWh — the rate at which electricity is sold to residential customers as well as the rate at which distributed solar is compensated. The study concludes that solar power provides a substantial public benefit because it reduces electricity prices due to the displacement of more expensive power sources, reduces air and climate pollution, reduces costs for the electric grid system, reduces the need to build more power plants to meet peak demand, stabilizes prices, and promotes energy security. These avoided costs represent a net benefit for non-solar ratepayers.

These generally positive PUC conclusions about the benefits of net metering have been supported by research done by a national lab and several think tanks. Important lab research has examined how substantially higher adoption of distributed resources might look.

In a forward-looking analysis of the financial impacts of net-metered energy on utilities and ratepayers, Lawrence Berkeley National Lab found that while high use of net-metered solar generation may decrease utility shareholders' earnings, it will have a "relatively modest" impact on ratepayers. The report examined solar penetration levels that are "substantially higher than [those that] exist today" — 10 percent compared to today's 0.2 percent — and concluded that “even at penetration levels significantly higher than today, the impacts of customer-sited PV on average retail rates may be relatively modest." The report further said that utilities and regulators "may have sufficient time to address concerns about the rate impacts of PV in a measured and deliberate manner"

Similarly, a growing number of academic and think tank studies have found that solar energy is being undervalued and that it delivers benefits far beyond what solar customers are receiving in net-metering credits:

• For instance, a review of 11 net metering studies by Environment America Research and Policy Center has found that distributed solar offers net benefits to the entire electric grid through reduced capital investment costs, avoided energy costs, and reduced environmental compliance costs. Eight of the 11 studies found the value of solar energy to be higher than the average local residential retail electricity rate: The median value of solar power across all 11 studies was nearly 17 cents per unit, compared to the nation’s average retail electricity rate of about 12 cents per unit.

• A 2015 cost-benefit study of net metering in Missouri by the Missouri Energy Initiative found that even accounting for increased utility administrative costs and the shifting of some fixed expenses, net metering is a net benefit for all customers regardless of whether they have rooftop solar. The study used values for two kinds of costs and two benefits and concluded that net metering’s “net effect” is positive. The typical solar owner pays only 20 percent less in fixed grid costs and costs the utility an estimated $187 per interconnection. Meanwhile, solar owners benefit the system through reduced emissions and energy costs.

• Likewise, a study by Acadia Center found the value of solar to exceed 22 cents per kWh of value for Massachusetts ratepayers through reduced energy and infrastructure costs, lower fuel prices, and lowering the cost of compliance with the Commonwealth's greenhouse gas requirements. This value was estimated to exceed the retail rate provided through net metering.

• In yet another study, researchers at the University at Albany, George Washington University, and Clean Power Research have found that solar installations in New York deliver between 15 and 40 cents per kWh to ratepayers. The study noted that these numbers provide economic justification for the existence of incentives that transfer value from those who benefit from solar electric generation to those who invest in solar electric generation.

In short, while the conclusions vary, a significant body of cost-benefit research conducted by PUCs, consultants, and research organizations provides substantial evidence that net metering is more often than not a net benefit to the grid and all ratepayers.

As to the takeaways, they are quite clear: Regulators and utilities need to engage in a broader and more honest conversation about how to integrate distributed-generation technologies into the grid nationwide, with an eye toward instituting a fair utility-cost recovery strategy that does not pose significant challenges to solar adoption.

From the state PUCs’ perspective, until broad changes are made to the increasingly outdated and ineffective standard utility business model, which is built largely around selling increasing amounts of electricity, net-metering policies should be viewed as an important tool for encouraging the integration of renewable energy into states’ energy portfolios as part of the transition beyond fossil fuels. To that end, progressive regulators should explore and implement reforms that arrive at more beneficial and equitable rate designs that do not prevent solar expansion in their states. The following reforms range from the simplest to the hardest:

• Adopt a rigorous and transparent methodology for identifying, assessing, and quantifying the full range of benefits and costs of distributed generation technologies. While it is not always possible to quantify or assess sources of benefits and costs comprehensively, PUCs must ensure that all cost-benefit studies explicitly decide how to account for each source of value and state which ones are included and which are not. Currently methodological differences in evaluating the full value of distributed generation technologies make comparisons challenging. States start from different sets of questions and assumptions and use different data. For instance, while there is consensus on the basic approach to energy value estimation (avoided energy and energy losses via the transmission and distribution system), differences arise in calculating other costs and benefits, especially unmonetized values such as financial risks, environmental benefits, and social values. In this regard, the Interstate Renewable Energy Council’s “A Regulator’s Guidebook: Calculating the Benefits and Costs of Distributed Solar Generation” and the National Renewable Energy Laboratory’s “Methods for Analyzing the Benefits and Costs of Distributed Photovoltaic Generation to the U.S. Electric Utility System” represent helpful resources for identifying norms in the selection of categories, definitions, and  methodologies to measure various benefits and costs.

• Undertake and implement a rigorous, transparent, and precise “value of solar” analytic and rate-setting approach that would compensate rooftop solar customers based on the benefit that they provide to the grid. Seen as an alternative to ‘traditional’ net-metering rate design, a “value of solar” approach would credit solar owners for (1) avoiding the purchase of energy from other, polluting sources; (2) avoiding the need to build additional power plant capacity to meet peak energy needs; (3) providing energy for decades at a fixed prices; and (4) reducing wear and tear on the electric grid. While calculating the “value of solar” is very complex and highly location-dependent, ultimately PUCs may want to head toward an approach that accurately reflects all benefits and costs from all energy sources. Value of solar tariffs are being used in Austin, Texas (active use) and Minnesota (under development).

• Implement a well-designed decoupling mechanism that will encourage utilities to promote energy efficiency and distributed generation technologies like solar PV, without seeing them as an automatic threat to their revenues. As of January 2016, 15 states have implemented electric decoupling and eight more are considering it. Not surprisingly, it is states that have not decoupled electricity (such as Nevada) that are fighting net metering the hardest. Typically, decoupling has been used as a mechanism to encourage regulated utilities to promote energy efficiency for their customers. However, it can also be used as a tool to incentivize net metering by breaking the link between utility profits and utility sales and encouraging maximum solar penetration. Advocates of decoupling note that it is even more effective when paired with time-of-use pricing and minimum monthly billing.

• Move towards a rate design structure that can meet the needs of a distributed resource future. A sizable disconnect is opening between the rapidly evolving new world of distributed energy technologies and an old world of electricity pricing. In this new world, bundled, block, “volumetric” pricing—the most common rate structure for both residential and small commercial customers—can no longer meet the needs of all stakeholders. The changing grid calls, instead, for new rate structures that respond better to the deployment of new grid technologies and the proliferation of myriad distributed energy resources, whether solar, geothermal, or other.  A more sophisticated rate design structure, in this regard, would take into consideration three things: (1) the unbundling of rates to specifically price energy, capacity, ancillary services,  and so on; (2) moving from volumetric bloc rates to pricing structures that recognize the  variable time-based value of electricity generation and consumption (moving beyond just peak versus off-peak pricing to  fully real-time pricing); and (3) moving from pricing that treats all customers equally to a pricing structure that more accurately compensates for unique, location-specific and technology specific values.

• Move towards a performance-based utility rate-making model for the modern era. Performance based regulation (PBR) is a different way of structuring utility regulation designed to align a utility’s financial success with its ability to deliver what customers and society want. Moving to a model that pays the utility based on whether it achieves quantitatively defined outcomes (like system resilience, affordability, or distributed generation integration) can make it profitable for them to pursue optimal grid solutions to meet those outcomes. The new business model would require the PUC and utilities to make a number of changes, including overhauling the regulatory framework, removing utility incentives for increasing capital assets and kilowatt hours sold, and replacing those incentives with a new set of performance standard metrics such as reliability, safety, and demand-side management. New York’s Reforming the Energy Vision  proceeding is the most high-profile attempt in the country to implement a PBR model.

Options also exist for utilities to address the challenges posed by net metering:

• Utilities, most notably, have the opportunity to adjust their existing business models by themselves owning and operating distributed PV assets (though not to the exclusion of other providers).  On this front, utilities could move to assemble distributed generation systems, such as for rooftop solar, and sell or lease them to homeowners. In this regard, utilities have an advantage over third-party installers currently dominating the residential rooftop solar industry due to their proprietary system knowledge, brand recognition, and an existing relationship with their customers. Utilities in several states such as Arizona, California, and New York are investigating or have already invested in the opportunity.

• Furthermore, utilities can also push the envelope on grid modernization by investing in a more digital and distributed power grid that enables interaction with thousands of distributed energy resources and devices.

Ultimately, distributed solar is here to stay at increasing scale, and so state policies to support it have entered an important new transitional phase. More and more states will now likely move to update their net-metering policies as the cost of solar continues to drop and more homeowners opt to install solar panels on their homes.

As they do that, states need to rigorously and fairly evaluate the costs and benefits posed by net metering, grid fees, and other policies to shape a smart, progressive regulatory system that works for all of the stakeholders touched by distributed solar.

Utilities should have a shot at fair revenues and adequate ratepayers. Solar customers and providers have a right to cost-effective, reliable access to the grid. And the broader public should be able to expect a continued solar power boom in U.S. regions as well as accelerated decarbonization of state economies. All of which matters intensely. As observes the North Carolina Clean Energy Technology Center and Meister Consultants Group: “How key state policies and rates are adapted will play a significant role in determining the extent to which the [solar PV] industry will continue to grow and in what markets.”

On Tuesday, May 24, Nigerian Central Bank Governor Godwin Emefiele announced that the country will adopt a more flexible foreign exchange rate system in the near future. This move signals a major policy shift by Emefiele and President Muhammadu Buhari, who had until this point opposed calls to let the naira weaken. Many international oil-related currencies have depreciated against the dollar as oil prices began their decline in 2014. Nigeria, however, has held the naira at a peg of 197-199 per U.S. dollar since March 2015, depleting foreign reserves and deterring investors, who remain concerned about the repercussions of a potential naira devaluation. Following the announcement, Nigerian stocks jumped to a five-month high and bond prices rose in anticipation that a new flexible exchange rate regime would increase the supply of dollars and help attract foreign investors.

For now it remains unclear exactly what a more flexible system will entail for Nigeria, however, some experts suggest that the Central Bank may introduce a dual-rate system, which allows select importers in strategic industries to access foreign currency at the current fixed rate, while more generally foreign currency will be available at a weaker, market-related level. This new regime raises a number of questions, including how it will be governed and who will have access to foreign currency (and at what rate). On Wednesday, Nigeria’s parliament requested a briefing soon from Emefiele and Finance Minister Kemi Adeosun to provide additional clarity on the new system, although the date for such a meeting has not yet been set.

Earlier this month, Kenya announced plans to close the Dadaab refugee camp, located in northeast Kenya, amid security concerns. The move to close the camp has been widely criticized by international actors. United States State Department Press Relations Director Elizabeth Trudeau urged Kenya to “uphold its international obligations and not forcibly repatriate refugees.” The United Nations High Commissioner for Refugees stated that the closure of the refugee camp would have “devastating consequences.” Despite these concerns, this week, at the World Humanitarian Summit, Kenya stated that it will not go back on its decision and confirmed the closure of the refugee camps within a six-month period.

The camp houses 330,000 refugees, a majority of whom fled from conflict in their home country of Somalia. Kenya insists that the camp poses a threat to its national security, as it believes the camp is used to host and train extremists from Somalia’s Islamist group al-Shabab. Kenya also argued that the developed world, notably the United Kingdom, should host its fair share of African refugees. This is not the first time Kenya has threatened to close the refugee camp. After the Garissa University attacks last April, Kenya voiced its decision to close the refugee camps, although it did not follow through with the plan.

From May 23-27, Lusaka, Zambia hosted 5,000 delegates and participants for the 2016 Annual Meetings of the African Development Bank (AfDB), with the theme, “Energy and Climate Change.” Held in the wake of December’s COP21 climate agreement and in line with Sustainable Development Goals 7 (ensure access to affordable, reliable, sustainable and modern energy for all) and 13 (take urgent action to combat climate change and its impacts), the theme was timely and, as many speakers emphasized, urgent. Around 645 million people in Africa have no access to electricity, and only 16 percent are connected to an energy source. To that end, AfDB President Akinwumi Adesina outlined the bank’s ambitious aim: “Our goal is clear: universal access to energy for Africa within 10 years; Expand grid power by 160 gigawatts; Connect 130 million persons to grid power; Connect 75 million persons to off grid systems; And provide access to 150 million households to clean cooking energy."

As part of a push to transform Africa’s energy needs and uses, Rwandan President Paul Kagame joined Kenyan President Uhuru Kenyatta on a panel to support the AfDB’s “New Deal on Energy” that aims to deliver electricity to all Africans by 2025. Kenyatta specifically touted the potential of geothermal energy sources. Now, 40 percent of Kenya's power needs come from geothermal energy sources, he said, but there is still room for improvement—private businesses, which make up 30 percent of Kenya’s on-grid energy needs, have not made the switch yet.

As part of the meetings, the AfDB, the Organization for Economic Cooperation and Development (OECD), and United Nations Development Program (UNDP) also launched their annual African Economic Outlook, with the theme “Sustainable Cities and Structural Transformation.” In general, the report’s authors predict that the continent will maintain an average growth of 3.7 percent in 2016 before increasing to 4.5 percent in 2017, assuming commodity prices recover and the global economy improves.  However, the focus was on this year’s theme: urbanization. The authors provide an overview of urbanization trends and highlight that successful urban planning can discourage pollution and waste, slow climate change, support better social safety nets, enhance service delivery, and attract investment, among other benefits.

For more on urbanization in sub-Saharan Africa, see Chapter 4 of Foresight Africa 2016: Capitalizing on Urbanization: The Importance of Planning, Infrastructure, and Finance for Africa’s Growing Cities.

Event Information

The Brookings Doha Center (BDC) hosted a panel discussion on May 30, 2016, about the security of energy exports and energy transit from the Middle East and North Africa (MENA). The panelists were Robin Mills, nonresident fellow at the Brookings Doha Center; and Colonel Giuseppe Morabito, director of the Middle East Faculty at the NATO Defense College. Sultan Barakat, senior foreign policy fellow and director of research at the BDC, moderated the event, which was attended by members of Qatar’s diplomatic, academic, and media community.

Barakat introduced the session by stating that the current unsettled environment in the Middle East raises concerns over energy security, both within the region and amongst energy consumers in Europe, the United States, India, China, and elsewhere. Threats to energy infrastructure exist at all scales, from individual acts of crime, sabotage, and terrorism to major regional wars and conflicts. We have seen large swaths of land fall under the control of non-state actors while states struggle to protect their territories. The Middle East houses some of the most important chokepoints in the energy transit, but also happens to be one of the most unstable regions in the world. 

Mills started his remarks by highlighting paradoxes in the oil and gas markets today, where low global oil and gas prices are juxtaposed with high levels of global disruptions to energy transits. Concern over energy security is lacking as markets appear to pay less attention to risks, even though energy security faces some unprecedented challenges. Such indifference, he noted, may be appropriate for now given the oversupply and abundance of energy in the market. But even in the current market, some possible threats may have very severe effects on global energy supplies, threatening the economies of consumers, producers, and the global market alike.

Mills proceeded to list different risk scenarios. At the local level, he highlighted the threat of sabotage, where communities demanding a greater share of natural resources may block a pipeline or attack an export terminal; piracy, which, he argued, could emerge in regions beyond the coast of Somalia; and attacks by extremist groups, who are eager to get a hold on new sources of income. On a state level, there is the threat of major interstate wars between major exporters, which thankfully haven’t erupted yet.  Past interstate wars, however, have had very significant impacts on energy security. The 1973 war between Israel and Egypt lead to an embargo that triggered the first oil crisis. The 1980s Iran-Iraq war resulted in severe damage to the oil production facilities of both countries and involved a tanker war which destroyed tankers passing through the Strait of Hormuz, resulting in an intervention by both the United States and the Soviet Union to protect shipping.

Hormuz, Mills continued, is one of numerous chokepoints—narrow channels along widely-used global sea routes that are crucial to the energy business. Given their narrowness, they tend to be obvious disruption targets. Hormuz carries about 17 million barrels per day (more than 20%) of oil exports. It is also the sole route for LNG export from Qatar, a crucial source of gas for East Asia and Europe. Other important chokepoints in the region are the Suez Canal, the southern entrance to the Red Sea, and the Bosporus Straits in Turkey. Any interruption of transit along those key areas would be highly detrimental.

Mills argued that, beyond attacks and wars, there is a broader and more diffuse threat to energy security, which has to do with investment. While it is true that investors can handle some level of risk in countries with moderate levels of insecurity like Nigeria, not all levels of insecurity can be worked with. At some point, insecurity can become too severe, deterring investment or even preventing it entirely. In the long term, this deters the development of promising new sources of oil and gas.

In response to a question from Barakat about NATO’s perspective on energy security in the Middle East, Morabito argued that NATO is particularly concerned about its gas supplies from the region, as most NATO countries rely on the region for gas. He argued that NATO’s policies, however, are primarily reactive, driven by events. No major events have interrupted energy supplies in recent times, so energy security is hardly on the agenda of NATO policymakers. There are more pressing issues these days, such as the threat of the Islamic State group (IS) and that of Russia’s Vladimir Putin.

In fact, Morabito continued, it is difficult to focus NATO’s attention on the issue because there doesn’t seem to be one. In the past, oil prices went up simply due to a war in Lebanon, which isn’t even an energy exporter. Today, however, we have a war that involves Saudi Arabia, the largest oil producer, but prices have been declining. The markets are very different today, mainly due to the development of shale technologies.

Nevertheless, Morabito noted that he thinks NATO, or some NATO nations, have intervened to secure their energy interests by training interstate groups such as the Kurds in Iraq or paying tribesmen in Algeria to protect pipelines that flow towards Europe. He noted that protecting pipelines is a costly business. A pipeline of 1,000 kilometers requires the presence of at least two soldiers every 50 meters; those two would have to work in shifts which necessitates hiring yet another two. Even then, an attack by only 50 militants would likely see the pipeline destroyed. This high cost makes it crucial to cooperate with local groups if proper security is to be insured.

Mills noted that European countries have become far less vulnerable to interruptions in supply, which were historically mainly caused by conflicts with Russia. He attributed that to interventions by the European Union to mitigate those vulnerabilities. He noted that in addition to institutional interventions, infrastructural development and market forces are also key in mitigating risks to the energy transit. When it comes to infrastructure, pipelines can be developed to bypass chokepoints, strategic storage can be built to provide countries with an emergency stock of oil and gas, and in some rare cases spare capacity can be employed to fill gaps in supply. Additionally, too often, government action to impose price controls, rationing, and export bans has proven to be counterproductive. It is important to allow the market to correct itself freely, although market mechanisms could be aided by better data.

After a Q&A session that asked about whether there truly are any real threats to Hormuz, the role that multi-national corporations can play in securing energy security, and threats to energy transit stemming from outside the MENA region.  Barakat concluded by thanking the guests and stating that energy security is yet another reason why the region should work to resolve its differences and put an end to regional wars and rivalries.

Video

• Risky routes: Energy transit in the Middle East

Event Materials

• EnergyTransitTranscript0516doc

On Friday, June 3, S&P Global Ratings announced that it would not downgrade South Africa’s credit rating to junk, letting South Africa breathe a sigh of relief. The outlook, however, remained negative. While some experts were confident that the rating would not be cut, most continued to warn that future economic or political turmoil could spark a downgrade later this year. The South African Treasury agreed, but remained positive releasing a statement saying:

Government is aware that the next six months are critical and there is a need to step up the implementation [of measures to boost the economy] … The benefit of this decision is that South Africa is given more time to demonstrate further concrete implementation of reforms that are underway.

South Africa, whose current rating stands at BBB- (one level above junk), has been facing weak economic growth—at 1 percent—over past months. The International Monetary Fund has given a 2016 growth forecast of 0.6 percent. Many feared that a downgrade could have pushed the country into a recession. Borrowing by the government would have also become more expensive, especially as it tackles a 3.2 percent of GDP budget deficit for the 2016-2017 fiscal year.

Other credit ratings agencies also are concerned with South Africa’s economic performance. Last month, Moody’s Investors Service ranked the country two levels above junk but on review for a potential downgrade, while Fitch Ratings is reviewing its current stable outlook and BBB- rating.

For South African Finance Minister Pravin Gordhan’s thoughts on the South African economy, see the April 14 Africa Growth Initiative event, “Building social cohesion and an inclusive economy: A conversation with South African Finance Minister Pravin Gordhan.”

This week, the Extraordinary African Chambers—located in Dakar and established in collaboration with the African Union—sentenced former Chadian President Hissène Habré to life in prison. Habré seized power in 1982, overthrowing then President Goukouni Oueddei. He fled to Senegal in 1990 after being ousted by current Chadian President Idriss Deby. After he fled to Senegal, the African Union called on Senegal to prosecute Habré. In 2013, the Extraordinary African Chamber was created with the sole aim to prosecute Habré. The Habré trial is the first trial of a former African head of state in another African country.

Habré faced a long list of charges including crimes against humanity, rape, sexual slavery, and ordering killings while in power. According to Chad’s Truth Commission,  Habré’s government murdered 40,000 people during his eight-year reign. At the trial, 102 witnesses, victims, and experts testified to the horrifying nature of Habré’s rule. His reign of terror was largely enabled by Western countries, notably France and the United States. In fact, on Sunday, U.S. Secretary of State John Kerry admitted to his country’s involvement in enabling of Habré’s crimes. He was provided with weapons and money in order to assist in the fight against former Libyan leader Moammar Gadhafi. Said resources were then used against Chadian citizens.

Also this week, Simone Gbagbo, former Ivorian first lady, is being tried in Côte d’Ivoire’s highest court— la Cour d’Assises—for crimes against humanity. She also faces similar charges at the International Criminal Court though the Ivoirian authorities have not reacted to the arrest warrant issued in 2012. In March 2015, Simone Gbabgo was sentenced to 20 years in jail for undermining state security as she was found guilty of distributing arms to pro-Laurent Gbagbo militia during the 2010 post-electoral violence that left 3000 dead. Her husband is currently on trial in The Hague for the atrocities committed in the 2010 post-election period.

On Monday, May 30, South African chemical and energy company Sasol Ltd announced that Mozambique’s ongoing debt crisis and continuing low global gas prices would not slow down its Mozambican gas project. The company expressed confidence in a $1.4 billion processing facility upgrade stating that the costs will be made up through future gas revenues. In explaining Sasol’s decision to increase the capacity of its facility by 8 percent, John Sichinga, senior vice president of Sasol’s exploration and production unit, stated, “There is no shortage of demand … There’s a power pool and all the countries of the region are short of power.” In addition, last week, Sasol began drilling the first of 12 new planned wells in the country.

On the other hand, on Monday The Wall Street Journal published an article examining how these low gas prices are stagnating much-hoped-for growth in East African countries like Tanzania and Mozambique as low prices prevent oil companies from truly getting started. Now, firms that flocked to promising areas of growth around these industries are downsizing or moving out, rents are dropping, and layoffs are frequent. Sasol’s Sichinga remains positive, though, emphasizing, "We are in Mozambique for the long haul. We will ride the waves, the downturns, and the upturns."

On December 12, 2015, 195 countries adopted the Paris Agreement, the most ambitious climate change pact to date. The document lays out a plan to curb greenhouse gas emissions, among other climate-related initiatives. Participating countries must now find ways to translate those ambitions into policy, and answer important questions about financing, transparency and accountability, national implementation, and accelerated emissions reduction goals, to name but a few. But one issue looms large: coal.

Coal-fired electricity is responsible for producing 40 percent of the world’s power and about 70 percent of its steel. The coal industry employs millions worldwide and provides billions of people with electricity. Analysts estimate that the world has hundreds of years of coal reserves in the ground, at current consumption levels. Its abundance, low price, and global availability make it a difficult fuel source to give up. But despite coal’s advantages, it poses significant environmental and health risks. Ten percent of coal consists of ash, which contains radioactive and toxic elements. It is responsible for over $50 billion in medical costs annually in the European Union alone. The environmental consequences of coal use, such as water contamination and habitat destruction, are common. Burning coal adds millions of tons of dangerous particulates and greenhouse gases, including carbon, to the atmosphere.

States and societies around the world rely on coal, even though many of its dangers have been known for decades. If the Paris Agreement is to succeed, global leaders must address the reasons why many countries—particularly in the developing world—still rely on coal. Better yet, they must find new ways to provide coal-reliant countries with affordable, alternative energy, and invest in new technologies that could help mitigate coal’s negative consequences.

COAL ACROSS THE WORLD

Globally, coal production and consumption has risen almost continuously for more than 200 years. The International Energy Agency has estimated that the world burned approximately 7,876 million tons of coal in 2013, adding over 14.8 gigatons of carbon to the atmosphere. But global coal statistics do not tell us much about markets and trends. In fact, coal usage varies enormously around the world, with some regions transitioning away from the resource as others have increasingly embraced it.

For example, stringent environmental, health, and safety policies in the United States have put increasing pressure on the coal industry. Well-funded environmental groups have succeeded in closing coal-fired power plants, and many states on the country’s west coast and in its northeast have aimed to create a coal-free power grid. Yet market forces have turned out to be the nail in U.S. coal’s coffin. The rise of natural gas in the United States has gave the country’s electricity producers an incentive to shift away from coal. In fact, U.S. coal consumption declined from a billion tons in 2008, to roughly 850 million tons by 2013. This year, analysts suggest that coal will fuel only 32 percent of all U.S. electricity, and natural gas will become the country’s leading electricity source for the first time. As a result of low prices, low returns, and political controversy, investors have shied away from coal, which has caused major coal companies to struggle to stay afloat. Of all announced new electricity generation capacity in the United States, not a single megawatt is coal-fired. Although change is happening, it will likely be decades before coal is no longer an important fuel source in the U.S. economy. Canada’s coal sector faces similar pressures: weak demand from Asia, public opposition to the construction of new export facilities, domestic environmental legislation, and the shale boom have all taken their toll.

In Europe, stringent air quality controls and climate change regulations have cut the use of coal dramatically in Denmark, Sweden, and the United Kingdom. But the EU emissions trading scheme, which relies on carbon offsets and carbon dioxide caps, has proven disappointing. In fact, most European countries still lack an economically competitive and readily available alternative to coal. Plus, the coal industry still has political power in capitals like Berlin and Warsaw, which lowers the European common denominator for energy policy, as well as its policies that fight climate change.

Photo courtesy of REUTERS/James Regan/File Photo. Coal is stockpiled at the Blair Athol mine in the Bowen Basin coalfield near the town of Moranbah, Australia, June 1, 2012.

In Asia, both Japan and South Korea are set to expand their use of coal despite signing the Paris Agreement. After the Fukushima disaster, Japan has implemented ambitious renewables and energy efficiency policies, but those cannot take the place of its nuclear energy production on their own. These countries are entirely import dependent, which makes natural gas prices high. This, in turn, makes natural gas a less likely fuel source as the countries transition to greener electricity. In this context, high-efficiency coal plants appear to be a viable alternative, especially as nuclear power remains highly controversial.

And outside of advanced economies, coal often plays the role it once played in Europe and North America. For over a decade, China was the main engine of global coal consumption, driving booms in coal mining and shipping. China’s domestic coal production skyrocketed, and other countries, such as Australia, experienced coal booms to keep pace with Chinese demand. Although China produced and consumed almost as much coal as the rest of the world combined in 2014, it seems that the country’s consumption has peaked. But China will still rely heavily on coal-fired electricity for decades. The country remains a key player in steel production, and millions of its citizens continue to work in the mining industry, despite recent layoffs.

South Asian countries continue to invest heavily in new coal-fired electricity plants and industrial projects. India may appreciate the risks of climate change, but its chief concern is delivering low-cost power to 350 million of its citizens who lack electricity. Coal is set to play a prominent role in meeting such goals. Countries like Indonesia, Thailand, and Vietnam have followed suit as they search for low-cost electricity to power their countries.

In short, coal remains a big player in the global fuel mix, even as it faces tough challenges from stringent environmental regulations, competition from other fuel sources, and a lack of new investments.

Photo courtesy of REUTERS/Sheng Li/Files. A labourer carries honeycomb briquettes at a coal processing factory in Shenyang, Liaoning province in this December 2, 2009 file photo.

WHITHER COAL?

Different strategies apply in different parts of the world when it comes to eradicating coal, despite the global agreement in Paris. Just as there is not a global energy grid, there is also no single, global transition to lower-carbon energy. Although some countries are transitioning away from coal, others continue to transition toward it.

Second, pragmatism and persistence—rather than ideological purity—remain key values as countries transition towards low-carbon economies. Natural gas provides North America with a backup fuel as it transitions to green energy. Without major bulk terminals on the west coast, western U.S. coal producers will not find new markets for their products overseas. And in Europe, policymakers will have to make good on long-promised and long-delayed changes to energy policy and infrastructure. If Germany and other EU states are to achieve promised clean energy transitions, coal production must be scaled back substantially across the continent. European leaders must also build an “Energy Union” that will accelerate the flow of cross-border electricity, if they are to achieve the Paris Accord’s climate change goals. Europe must also reform its existing carbon pricing mechanisms. And across China, Europe, and North America, workers will have to be re-educated for new job opportunities as the coal market dries up.

But for now, coal still keeps the light on around the world. It powers new, high-tech economies, as well as a huge share of traditional manufacturing. If hundreds of millions of Africans and Asians are to gain access to electricity, new coal-fired power plants will have to come online in the years ahead. As coal continues to play a prominent role in industrial processes like steel and cement making, technological investments are required to limit its consequences.

To tackle these challenges, coal advocates, as well as some climate experts, suggest that more countries must invest in carbon capture and sequestration (CCS) research. But such investments are lagging, and the world would require several dozen CCS projects in order to make the technology commercially viable in the long term.

If the Paris Accord is to succeed, the earth’s atmosphere cannot remain a free dump for billions of tons of pollution every year. In fact, virtually all greenhouse gas emissions must be reduced. Countries can impose taxes, cap-and-trade schemes, and regulation to make this happen. Governments will have to design unique strategies that are custom fit to their countries, and, in some cases, find opportunities with their neighbors as well. For example, some private and public institutions have chosen to stop financing coal-fired projects, and the Obama administration has indicated it will not give out new leases for coal mining on federal land. Others will choose to build more coal-fired plants until the alternatives are cheaper, or until someone pays them not to.

Globally, coal may indeed be at the beginning of the end. But the energy transition is not strictly global. It is also national, regional, and local. Coal remains economically competitive—attractive even—in many parts of the world. Some countries will wage wars on coal, which will be as much economic and financial as they are political. But some countries, like India, will host coal booms regardless of the consequences. After Paris, there is no point in ignoring coal. It will be powering the world—and the world’s debates—for decades to come.

This piece was originally published by Foreign Affairs.

This election cycle, what will separate Democrats from Republicans on energy policy and their approach to climate change? Republicans tend to be fairly strong supporters of the fossil fuel industry, and to various degrees deny that climate change is occurring. Democratic candidates emphasize the importance of further expanding the share of renewable energy at the expense of fossil fuels, and agree that climate change is a real problem—with some saying the challenge trumps most, if not all, other U.S. security concerns.

Now that there are presumptive nominees for both major political parties, it’s an important moment to outline, in broad strokes, the positions of Secretary Hillary Clinton and businessman Donald Trump. We realize that Democratic Presidential candidate Bernie Sanders has not dropped out of the race, but note that it is fairly unlikely at this point that he would clinch the nomination.

Clinton: Building on the Obama legacy 

Secretary Clinton has laid out the most comprehensive and detailed energy and climate policy proposals of the candidates to date. They are in essence a continuation, and in some cases a further expansion, of existing White House policies under President Obama. The Secretary has stated that she wants the United States to be the “clean energy superpower of the 21st century.”

This starts with the notion that climate change is an existential threat, which the global community has to address as soon as possible. In order to do that, in her view, the United States needs to continue to show leadership on the international stage, as the Obama administration sought to do surrounding the Paris agreement in December 2015. This will require substantial reforms to expand low-carbon options, including nuclear energy to some degree, while tightly regulating fossil fuels (and gradually phasing them out). 

[S]he wants the United States to be the “clean energy superpower of the 21st century.”

The first casualty of this transformation is the coal industry, which Clinton has explicitly acknowledged. She presented a $30 billion plan to revitalize communities where coal production is currently an important industry and job creator, for example, and has campaigned with this message in various state primaries. Implicitly, Secretary Clinton does not seem to believe in the economic viability of carbon capture and sequestration in the United States—this is despite the fact that most analyses, including those of the Intergovernmental Panel on Climate Change (IPCC), suggest that this technology could be a cost-efficient tool in a wider carbon emission mitigation portfolio. 

Clinton sees natural gas as a bridge fuel, though at this point it’s not clear how long that bridge is. Questions remain about the role that natural gas can play in scenarios of deep decarbonization in 2030 and beyond. At the moment, the gas industry is rather nervous of the Secretary’s statement that she’d increase regulations on, in particular, the fracking industry—if her conditions came to fruition, there would very few places where fracking would continue. 

Secretary Clinton believes that oil consumption has to be cut substantially in the coming years, and she has suggested that new drilling in places like the Arctic, off the Atlantic Coast, and on federal lands would be discouraged or banned. She has previously opposed crude oil exports, though we would not anticipate a roll-back of existing policies (in December 2015, the Obama administration lifted the decades-old ban). 

Clinton foresees a new energy economy built on rapidly increasing shares of renewable energy, which should comprise 25 percent of the U.S. fuel mix by 2025 according to her plan (solar energy would be a key focus, with half a billion panels to be installed by the end of her first term). To facilitate this transition, she presented an elaborate energy infrastructure plan to modernize the U.S. grid and improve efficiency in reviewing and approving projects. 

Tax credits to support renewables would be continued under a Clinton White House, whereas fossil fuel subsidies would be phased out. Increased energy efficiency, including harmonization of vehicle efficiency and fuel standards, are high on her agenda as well. The Secretary also supports the Clean Power Plan that the Environmental Protection Agency under the Obama administration has launched, and which is currently on hold in the Supreme Court. 

On the international stage, Clinton supports the Paris agreement on climate change. Should she win the presidency in November, she would make an effort to take this Treaty to the next step, thus continuing U.S. leadership. That would mean reinforcing U.S. leadership along the lines described above, while helping address current uncertainties about finance, transparency, and accountability, to name only a few challenges that remain.

Trump: Drill, baby, drill

Although Donald Trump’s candidacy remains highly controversial, he is now the presumptive Republican nominee for president. To the extent that we know any detailed plans, quod non, it is safe to say that his views on energy and climate change are diametrically opposed to most of Clinton’s. Broadly speaking, Mr. Trump has come out as a fervent supporter of the fossil fuel industry, and has expressed skepticism about the economic viability of renewable energy.

Mr. Trump’s views start with the belief that climate change is not man-made. In the past, the controversial businessman has suggested that climate change might be a hoax invention from China, in order to undermine U.S. industrial interests and job creation. This starting point allows Mr. Trump to be extremely supportive of existing industrial interests (if carbon and other greenhouse gas emissions are not a problem, the thinking goes, then business as usual is the way to go). 

In a speech in North Dakota in late May, Mr. Trump laid out some broad initial ideas for his energy policy. He declared that under his presidency the United States would “accomplish complete American energy independence,” leaving unaddressed arguments about what that would mean for existing international energy trade. 

It is probably safe to say that Mr. Trump would like to further expand oil, gas, and coal production in the country. The latter, in particular, is remarkable: even coal executives have declared that market forces (particularly very competitive natural gas) have been the primary threat to the coal industry. Since Mr. Trump is also a strong supporter of the natural gas industry—and considering the challenges of building new bulk terminals for exports—it is unclear how a revitalization of the coal industry would occur. 

If climate change is a hoax, it will come as no surprise that Mr. Trump will not support efforts to mitigate carbon and other greenhouse gas emissions.

Contrary to his opponent, Mr. Trump would also like to revoke restrictions on drilling for oil and gas, and would permit production on federal lands. He also supports further expansion of energy infrastructure, and would, if elected, ask Trans Canada to resubmit a permit application for the Keystone pipeline, which he’d approve. He has caveated his support for projects like these by demanding that a portion of the revenues from oil and gas flows be redistributed to local communities, to compensate them for intrusion on their private property. Mr. Trump has also indicated that he wants to use revenues from oil and gas production to rebuild U.S. infrastructure more broadly.

If climate change is a hoax, it will come as no surprise that Mr. Trump will not support efforts to mitigate carbon and other greenhouse gas emissions. The candidate has called the Obama administration’s Clean Power Plan “stupid,” and when asked what he would do about the Paris agreement on climate change, he said he’d cancel it. 

Though Trump says the United States must pursue all forms of energy—including renewables—he has expressed skepticism about their economic viability, calling solar energy “very expensive.” Wind energy received similar pejorative feedback, since Trump says it kills eagles and is noisy. During one of the few debates about renewable energy during the Iowa primary, he voiced his support for blending biofuels in vehicles. 

To the polls

The 2016 U.S. presidential election will have a profound impact on global affairs. Not only will it affect a range of security and economic issues in important ways, it also means a lot for global energy and climate policy. Will the United States continue on the trajectory that President Obama has started and continue a major energy transition strategy? Or will it shift course, potentially undermining existing domestic policies and investments, as well as international obligations? In November 2016, the American people will decide.

The debate surrounding net energy metering (NEM) and the appropriate way to reform this policy is under scrutiny in many U.S. states. This is highly warranted since NEM policies do indeed need reforming because NEM often results in subsidies to private (rooftop) solar owners and leasing companies. These subsidies are then “paid for” by non-NEM customers (customers without private rooftop solar installations). The fundamental source of the NEM subsidy is the failure of NEM customers (customers with private rooftop solar installations) to pay fully for the grid services that they use 24/7. These subsidies are well-documented and underpin much of the regulatory reform efforts underway across the United States.[1]

In a recent Brookings paper, “Rooftop solar: Net metering is a net benefit,” Mark Muro and Devashree Saha contend that net metering is a net benefit for non-NEM customers.[2] I fundamentally disagree with their findings, and argue that NEM is not a net benefit; it is, in fact, a tariff that much of the time results in a subsidy to NEM customers and a cost shift onto non-NEM customers. As Executive Director of the Institute for Electric Innovation, a non-lobbying organization focused on trends in the electric power industry, I have followed this debate and written about it for several years.

Much of the talk about NEM focuses too often on the “value” of the energy that is sold back to the grid by a NEM customer. In reality, the amount of energy sold back to the grid is relatively small. The real issue is the failure of NEM customers to pay fully for the grid services that they use while connected to the grid 24/7, as shown in Figure 1.[3] Customers need to constantly use the grid to balance supply and demand throughout the day, and the cost of these grid services can be sizeable. In fact, for a typical residential customer in the United States with an average electricity bill of $110 per month, the actual cost of grid services can range from $45 to $70 per month–however, the customer doesn’t see that charge.[4] That means, in the extreme, if a customer’s energy use “nets” to zero in a given month because the customer’s private solar system produced exactly what the customer consumed, that customer would pay $0 even though that customer is connected to the local electric company’s distribution grid and is utilizing grid services on a continuous around-the-clock basis.[5]

Although exactly netting to zero energy in a month is highly unlikely, this example demonstrates the point that the customer would pay nothing, despite using grid services at a cost ranging from $45 to $70 per month. Over the course of one year, this customer could receive a subsidy resulting from NEM of between $540 and $840. Over the life of a private rooftop solar system, which ranges from 20 to 25 years, this is a significant subsidy resulting from NEM.

Granted, this is an extreme example, and most NEM customers will pay for some portion of grid services. However, the fundamental source of the NEM subsidy is the failure of NEM customers to pay fully for the grid services that they use 24/7, and the cost of these services can be quite substantial. When a NEM customer doesn’t pay for the grid, the cost is shifted onto non-NEM customers.[6] It is a zero-sum game; plain and simple. This is the elephant in the room.

This issue was directly addressed by Austin Energy when the company implemented a “buy-sell” arrangement for the private rooftop solar customers in its service territory. The rationale for the buy-sell approach is that the customer buys all of the energy that is consumed on-site through the electric company’s retail tariff and sells all of the energy produced by their private rooftop solar system at the electric company’s avoided cost. This addresses the “elephant in the room” because, by buying all energy consumed at the retail tariff, the customer does pay for grid services that are largely captured through the retail tariff. It is an unfortunate fact that under ratemaking practices today in the United States, the majority of fixed costs (i.e., grid and other costs) are captured through a volumetric charge.

Hence, I fundamentally disagree with the Muro/Saha paper–NEM does need to be reformed. NEM is not a net benefit; it is a tariff that the much of the time results in a cost shift onto non-NEM customers. One of the first studies to quantify the magnitude of the NEM subsidy was conducted by Energy+Environmental Economics (E3) for the California Public Utilities Commission (CPUC) in 2013. There was no mention of this analysis for the CPUC in the Muro/Saha paper. The E3 study estimated that NEM would result in a cost shift of $1.1 billion annually by 2020 from NEM to non-NEM customers if current NEM policies were not reformed in California.[7] A cost shift of this magnitude–paid for by non-NEM customers–was unacceptable to California regulators. As a result, California regulators set to work to reform rates in their state; many other states followed suit and conducted similar investigations of the magnitude of the NEM subsidy.

In reviewing NEM studies, Muro and Saha chose to focus on a handful of studies that show that net metering results in a benefit to all customers. In this small group of NEM studies, they included a study that E3 conducted for the Nevada Public Utilities Commission (PUC) in 2014–perhaps the most well-known and cited of the five studies included in the Muro/Saha paper. Very soon after the E3 Nevada study was published, the cost assumptions for the base-case scenario which showed a net benefit of $36 million to non-NEM customers (assuming $100 per MWh for utility-scale solar) were found to be incorrect, completely reversing the conclusion. The $36 million benefit associated with NEM for private rooftop solar turned into a $222 million cost to non-NEM customers when utility-scale solar was priced at $80 per MWh.[8] Today, based on the two most recent utility-scale contracts approved by the Nevada PUC, utility-scale solar has an average lifetime (i.e., levelized) cost of $50 per MWh, meaning that the NEM cost shift would be far greater today. In February 2016, the Nevada PUC stated that “the E3 study is already outdated and irrelevant to the discussion of costs and benefits of NEM in Nevada…”[9] Hence, because the E3 study for the Nevada PUC that the Muro/Saha paper included has been declared outdated and irrelevant to the discussion and because costs for utility-scale solar have declined significantly, that study does not show that NEM provides a net benefit.

No doubt there is an intense debate underway about NEM for private rooftop solar, and much has changed in the past two years in terms of both NEM policies and the growth of private solar projects:

• First, several state regulatory commissions now recognize that the NEM cost shift is both real and sizeable and that all customers who use the grid, including NEM customers, need to pay for the cost of the grid. As a result, many electric companies have proposed and state regulatory commissions have approved increases in monthly fixed charges over the past few years; this partially addresses the issue of NEM customers paying for the cost of the grid services that they use.
• Second and related, getting the pricing right for distributed energy resources of all types is important because we expect those resources to grow significantly in the future. Work is underway in this area and it is one focus of the New York Reforming the Energy Vision proceeding; but there is still much to be done.

By focusing on a select group of studies that show that NEM benefits all customers (as stated by the authors); by excluding the E3 study for the CPUC which was fundamental to the NEM cost shift debate; and by not providing an update on the NEM debate today, I believe that the Muro/Saha paper is misleading.

In the second part of their paper, Muro and Saha suggest some helpful regulatory reforms such as moving toward rate designs that “can meet the needs of a distributed resource future” and moving “toward performance-based rate-making (PBR).” Some electric companies have already implemented PBR or some type of formula rate and PBR is under discussion in several states.[10] Lawrence Berkeley National Labs is looking closely at this and related issues in its Future Electric Utility Regulation series of reports currently underway.[11]

Mura and Saha also suggest decoupling as a way forward–I disagree. In my view, decoupling is a not solution for private rooftop solar. Revenue decoupling is currently used to true-up revenues that would otherwise be lost due to declining electricity sales resulting from electric company investments in energy efficiency (EE). Decoupling explicitly shifts costs from participating EE customers to non-participating EE customers causing the same cost-shifting problem that is created by NEM. However, a fundamental difference is that the magnitude of the cost shifting onto non-NEM customers is on a much larger scale than the cost shifting due to EE. A recent study revealed that decoupling rate adjustments for EE are quite small–about two to three percent of the retail rate.^[12] In contrast, as described earlier in this paper, a NEM customer could shift a significant cost onto non-NEM customers (and the NEM cost shifting is essentially invisible to customers, which is one reason that NEM customers do not believe they are subsidized).[13]

Finally, Muro and Saha suggest that electric companies should invest in a more digital and distributed power grid. In fact, electric companies across the United States are doing just that. In 2015, electric companies invested $20 billion in the distribution system alone and this is expected to continue. Over the past five to six years, electric companies invested in the deployment of nearly 65 million digital smart meters to about 50 percent of U.S. households. In addition, electric companies are investing in thousands of devices to make the power grid smarter and more state-aware. Today, in states such as California, Hawaii, and Arizona, electric companies are investing to enable and integrate the distributed energy resources that are growing exponentially. And, in some states–where regulation allows–electric companies are offering rooftop solar or solar subscriptions to their customers.

No doubt, the electric power industry is undergoing a period of profound transformation–our power generation resource mix is getting cleaner and more distributed; the energy grid is becoming more digital; and customers have different expectations.[14]

Collaboration, good public policy, and appropriate regulatory policies are critical to a successful transformation of the power sector. In the context of this paper, this means reforming NEM so that private rooftop solar customers who use the energy grid pay for the grid. One straightforward approach is to require NEM customers to pay a higher monthly fixed charge thereby reducing the cost shift.[15] Ultimately the challenge is to make the transition of the electric power industry–including the significant growth in private rooftop solar and other distributed energy resources–affordable to all customers.

Lisa Wood is a nonresident senior fellow in the Energy Security and Climate Initiative at Brookings. She is also the executive director of the Institute for Electric Innovation and vice president of The Edison Foundation whose members include electric companies and technology companies.

Saudi deputy crown prince and defense minister Mohammad bin Salman is just wrapping up a heavily hyped visit to Washington, aimed at reinforcing the kingdom’s partnership with the United States. Recent years have frayed what is traditionally the central strategic relationship for Riyadh, principally over the Obama administration’s nuclear diplomacy with Iran.

Since the conclusion of the Iranian nuclear deal last July, the perennial antagonism between Riyadh and Tehran has reached a dangerous pitch, fueling the violence that rages in Syria, Iraq, and Yemen and the undercurrent of instability that saturates the region. And the fallout of their rivalry has left its mark well beyond the boundaries of the Gulf, exacerbating volatile energy markets and, by extension, the global economy. 

Within OPEC, Riyadh and Tehran are eyeing each other warily, and their continuing differences torpedoed a proposed ceiling on oil production at OPEC’s latest meeting. The outcome was not surprising; a similar effort to agree on a production freeze between the group and a handful of non-OPEC producers fizzled in April. In the meantime, any incentives for drastic measures to address soft oil prices have abated as oil prices creep back up to approximately $50 a barrel. 

Iran and Saudi Arabia have plenty of reasons to continue pumping for the foreseeable future. Since the lifting of nuclear-related sanctions in January, Iranian leaders have been determined to make up for lost time and lost revenues, already defying expectations by quickly raising production to levels that hadn’t been reached since November 2011 and aggressively cutting prices in hopes of winning back its pre-sanctions export market. 

The centrality of oil to the legitimacy and autonomy of both regimes means that these plans are little more than publicity stunts.

Meanwhile, Saudi Arabia appears prepared to continue pumping at record-high levels, part of a larger strategy aimed at maintaining market share and driving down non-OPEC production. The two states’ economic incentives are compounded by their fierce geostrategic and sectarian rivalry, which has intensified, as evidenced by the standoff over Iranian participation in the annual pilgrimage to Mecca.

But even as the two states duel over oil production and prices, both Saudi Arabia and Iran are conspicuously planning for a post-oil future. Leaders in both countries have decreed an end to the era of oil dependency, endorsing ambitious blueprints for restructuring their economies that—if implemented—would ultimately transform state, society, and the wider region. The centrality of oil to the legitimacy and autonomy of both regimes means that these plans are little more than publicity stunts. Still, just imagine for a moment what it would mean for Iran, Saudi Arabia, and the Middle East if these grandiose agendas were adopted.

Competing and complementary visions

Tehran’s plan actually dates back more than a decade, with the 2005 release of its “20 Year Perspective” (sometimes called “Vision 2025”). The plan laid out extravagant expectations: rapid growth and job creation, diversification away from oil, a knowledge-based economy. Intervening developments—sanctions that targeted Iran’s oil exports and helped expand non-oil trade—have only bolstered the rhetorical commitment of Iran’s supreme leader, Ayatollah Ali Khamenei, to a “resistance economy” in which oil exports constitute a minor part.

“One of our most serious losses is dependence on oil,” Khamenei bemoaned in a 2014 speech. “I am not saying that oil should not be used. Rather, I am saying that we should reduce our dependence on selling crude oil as much as we can.” 

Not to be outdone, Saudi Deputy Crown Prince Salman announced Saudi “Vision 2030,” to address what he described as “an addiction to oil.” The plan, which has met with equal doses of fanfare and skepticism since its announcement last month, aims to create a “thriving economy” and end Saudi dependence on oil revenues by 2020. Vision 2030 includes provisions to sell off a small stake in the kingdom’s state oil company, Saudi Aramco, and create the world’s largest sovereign wealth fund to manage the country’s income, as well as goals of creating 450,000 new private sector jobs, cutting public sector wages, and tripling the country’s non-oil exports all within the same abbreviated time frame.

Jeopardizing domestic stability

There is one hitch, however: these aspirations, though laudable, are preposterously unmoored from current political and economic exigencies. The institutions of governance and the structure of power in resource-rich states such as Saudi Arabia and Iran are organized around the state’s role as purveyors of vital social and economic goods. Riyadh and Tehran distribute cash handouts, provide jobs in already-bloated state bureaucracies, and levy few taxes. Diversifying away from reliance on oil would essentially require Riyadh and Tehran to radically curtail this distributive role, inviting historic social and political changes that could ultimately compromise regime ideology and weaken state legitimacy. 

[T]hese aspirations, though laudable, are preposterously unmoored from current political and economic exigencies.

In Saudi Arabia, the supply of these benefits is central to the monarchy’s legitimacy. To diversify away from oil, which currently accounts for over 70 percent of government revenues, Riyadh would have to drastically cut spending, far more than it already has. Not only would this further slash subsidies and hike fees, it would also effectively force Saudi workers—two-thirds of whom are employed by the state—to take up private sector jobs, 80 percent of which are currently staffed by expatriates. To accomplish this transition would require fundamental changes to the incentive structure for the Saudi labor force: a much broader willingness to accept low-skill, low-wage jobs, as well as the requisite improvements in education and productivity to support larger numbers of Saudi nationals moving into private sector positions.

For the Saudi economy to be truly competitive, Riyadh would have to initiate dramatic changes to a central component of the Saudi social compact—women’s rights and freedoms. The Vision 2030 document boasts that over 50 percent of Saudi university graduates are women and pledges to “continue to develop their talents, invest in their productive capabilities and enable them to strengthen their future and contribute to the development of our society and economy.” 

But the domestic Saudi labor force is overwhelmingly male, and even the plan’s modest aspirations to raise female participation in the workforce from 22 to 30 percent are likely to run into logistical and social obstacles. Shortly after announcing Vision 2030, Deputy Crown Prince Salman said Saudi Arabia is not yet ready to let women drive. A diversified economy will not emerge in the kind of constricted social environment mandated by the Saudi interpretation of sharia (Islamic law). 

Iran’s Islamic Republic doesn’t have the same degree of gender segregation, but Iran’s official interpretation of Islam has still constrained female participation in the workforce. Iran employs an equally low percentage of women—according to a 2014 U.N. report around 16 percent—and women’s unemployment is more than double that of men (nearly 20 percent).

A Saudi man walks past the logo of Vision 2030 after a news conference in Jeddah, Saudi Arabia June 7, 2016. Photo credit: Reuters/Faisal Al Nasser.

The bigger challenge for Iran will be truly opening up its economy to foreign direct investment. This remains hotly contested among the leadership, even in the aftermath of the nuclear agreement and the lifting of related sanctions. While there is some consensus around the need for foreign capital and technology, hardliners including Khamenei are determined to insulate Iran from any accompanying cultural influence and dependency. As the supreme leader recently inveighed, the global economy is “a plan and system that has been devised mainly by Zionist capitalists and some non-Zionists with the purpose of usurping the economic resources of the whole world...If a country merges its economy with the global economy, this is not a source of pride, rather it is a loss and a defeat!”

This deeply-rooted paranoia has provided a convenient platform for the Islamic Republic to galvanize citizens’ loyalty to the state and hostility to outside interference. And it also inhibits the liberalization that makes foreign investment possible: measures to enhance transparency and security, develop more attractive legal and fiscal frameworks, shrink the role of the state, and undertake an array of other structural reforms. Without these measures, Tehran will struggle to capitalize on its extraordinary reengagement with the world. 

While Saudi Arabia has maintained a more consistent and mutually beneficial pattern of foreign investment, its leadership too will have to revamp its approach if it is to broaden its economic base. For Riyadh, the challenge is less one of attracting foreign capital than of developing a sustainable influx of technology and expertise to develop sectors other than energy. The kingdom will also have to overcome serious regulatory hurdles and a proclivity for mammoth (and often white elephant) projects.

Compromising regional clout

Riyadh and Tehran will need to balance their economic aspirations and their approach to the region, too. Historically, their role in global energy markets has largely shielded both states from the fallout of regional instability. The world’s need for reliable oil at reasonable prices has inculcated the commitment of outside powers to secure transportation of resources and considerable autonomy for Riyadh and Tehran from the implications of their own policies. 

As a result, Saudi Arabia and Iran can fund nefarious activity across the region, violate the civil and human rights of their citizens and other residents, and carry out belligerent foreign policies without severe repercussions for their oil revenues. Only in the past five years has Tehran seen the limits of the world’s reluctance to jeopardize its investment with a major oil exporter; and the recent reversal of the U.N. condemnation regarding the Saudi-led coalition in Yemen demonstrates that Riyadh remains insulated.

Saudi Arabia and Iran can fund nefarious activity across the region, violate the civil and human rights of their citizens and other residents, and carry out belligerent foreign policies without severe repercussions for their oil revenues.

Regional developments make the prospect of economic diversification even less likely, as sensitivity to such developments will only increase if either country successfully develops its non-oil sectors. At the same time, regional stability is a basic prerequisite for economic diversification. Robust growth and good governance throughout the Middle East would provide the optimal context for the economic transformation of Iran and Saudi Arabia, since the marketplace for their non-oil exports is concentrated in the immediate neighborhood. But such transformation would require both countries to put economic priorities that serve their general populations above the ideological and religious agendas—supported by oil rents—that propel their regional and international influence and that provide a large portion of their autonomy in foreign policymaking. 

Technocrats in both countries understand this intuitively. At a 2015 conference on Iran’s economy, President Hassan Rouhani wondered “How long can the economy pay subsidies to politics?” He added that the country’s economy “pays subsidies both to foreign policy and domestic policy. Let us try the other way round for a decade and pay subsidies from the domestic and foreign policy to the economy to see [what] the lives and incomes of people and the employment of the youth will be like.” The problem, of course, is political will: neither country is prepared to elevate the interests of its people over the demands of ideology.

Imagining an unlikely future

Can either Iran or Saudi Arabia really kick the oil habit? It seems exceptionally unlikely. Even as Khamenei extols the need for inward-focused development, Tehran is racing to expand crude output level to four million barrels per day by March 2017. 

Oil enabled the creation of the modern Middle Eastern state and fueled the rise of both countries to regional predominance. Oil is a vector for their regional rivalry, and it provides prestige and funds to be used in other arenas of competition. A genuine diversification of the two largest economies in the Middle East and North Africa would jeopardize their revenue streams and domestic legitimacy, as well as their efforts to assert their primacy across the Islamic world.

[N]either country is prepared to elevate the interests of its people over the demands of ideology.

“All success stories start with a vision,” Deputy Crown Prince Salman is quoted as saying on the Vision 2030 website. But vision is insufficient to bridge the gap between aspiration and reality; a serious agenda to implement either the Saudi or the Iranian vision would require painful compromises to regime ideology and a fundamental overhaul of the institutions and the structure of power in both countries. 

Imagine, though, for a moment, that these far-fetched ambitions were quite serious, and that both the Saudi and Iranian leadership were determined to do what was necessary to truly wean their economies off oil dependence. Consider what it might mean for the region if these grandiose ambitions were not simply the illusions of overpriced consultants and embattled technocrats—if a leadership emerged in one or both of the Middle East’s most powerful actors prepared to invest political capital in a genuine transformation of priorities and policies. What might be possible if Tehran and Riyadh sought to compete for economic opportunities instead of fueling violence and sectarianism around the region? If instead of a vicious sectarian and geopolitical rivalry, these two old adversaries engaged in a race to the top?

What will it take to move these visions from wishful thinking to reality? More than rhetoric, to be sure. But even the articulation of improbable objectives will have its impact. As documented in a recent book, Iran’s post-revolutionary experience demonstrates that the regime’s reliance on promises of economic gains has generated public expectations for effective and accountable governance. Now Iranians and Saudis have been told by their leaders—who happen to be officially infallible—that the time has come to transcend oil. What might happen if they believe it?

Editors’ Note: Science diplomacy can help countries solve on-the-ground challenges and improve standards of living for their citizens, writes David Hajjar. But it can also lay groundwork for improving relations through functional, scientific cooperation that is less politicized. This post originally appeared on Lawfare.

In the Middle East, governments and non-state actors alike have tried all forms of diplomacy to solve the challenges they face, with mixed results: shuttle diplomacy by the United States between the Israelis and Palestinians worked for a time, great-power diplomacy over the Syrian civil war largely hasn’t, and direct negotiations with unsavory groups like the Taliban have moved in fits and starts. 

But progress can come from unlikely sources, and science diplomacy—whereby experts collaborate scientifically to address common problems and build constructive international partnerships—has more potential than is often recognized. Science diplomacy can of course help countries solve on-the-ground challenges and improve standards of living for their citizens. But it can also lay groundwork for improving relations in a region often defined by tension (if not outright conflict) through functional, scientific cooperation that is less politicized. 

Efforts in science and technology, on the one hand, and diplomacy on the other, can achieve more if they are thoughtfully merged—rather than siloed. Science diplomacy, therefore, can contribute to peace- and security-building in the Middle East (and with the United States) in unique ways. 

Science and global governance

Across the world, science diplomacy has helped set the stage for advancing foreign policy and global governance goals.

The 2015 nuclear deal between Iran and the P5+1 illuminated how negotiating over and collaborating on science and technology issues can be an important gateway to achieving significant foreign policy goals. Direct (and often very technical) diplomacy between U.S. Secretary of Energy Ernest Moniz and the head of the Atomic Energy Organization of Iran, Ali Akbar Salehi, was key to achieving the framework agreement, as was collaboration between Iranian and Western nuclear scientists more broadly. Provided that the agreement is thoroughly enforced, it’s a major victory for global nuclear nonproliferation efforts—and much credit goes to effective science diplomacy. 

Global efforts to combat climate change are another area in which science diplomacy has had a real impact on policy. The United Nations’ Intergovernmental Panel on Climate Change has become a model for critical science policy research and recommendations. The 2015 conference in Paris brought together hundreds of political leaders and experts to examine the scientific evidence that the globe is warming, discuss remedies, and chart a path forward that can help slow environmental damage. So, science diplomacy was again central—this time in shaping and implementing the global climate governance framework. 

Another area where we have observed substantive gains from science diplomacy is the global management of infectious diseases. The Zika outbreak in Latin America, Ebola epidemic in West Africa, dengue in the Caribbean and Asia, MERS in the Gulf region and in South Korea, and the global threat of pandemic influenza all underscore that international cooperation is key to fighting modern plagues, which spread more rapidly in an era of constant global travel. In some cases more than in others, political leaders have devoted considerable resources to promoting international scientific cooperation—whether in clinical monitoring, medical interventions, research into pathogen biology and diagnostics, and treatments (including vaccine development). In fact, the global response to severe acute respiratory syndrome (SARS) is an example where international collaboration helped identify affected populations and coordinate treatment through the WHO Global Alert and Response System (which has identified new cases in Europe, the Middle East, Australia, Canada, Vietnam, Taiwan, and Hong Kong). The system’s main goal is to send supplies and medical specialists (including epidemiologists), design clinical trials, provide diagnostic tests, identify modes of transmission, and provide treatment. This coordinated response effort has controlled the pandemic.

Science in a fraught region

In the Middle East, opportunities abound for science diplomacy. Not only can this type of approach help solve practical, quality-of-life challenges—from energy to health and beyond—it can bring together expert communities and bureaucracies. In the process, it can contribute to more normalized people-to-people and government-to-government relations. Even at the height of the Cold War, for example, U.S. and Russian nuclear scientists and other experts worked together to monitor each other’s nuclear facilities; even though Moscow and Washington had nuclear-armed intercontinental ballistic missiles aimed directly at each other, bureaucratic cooperation on technical issues became a normal part of the relationship and helped enhance transparency and trust.

In the energy sector, for example, innovation in science and technology will play a crucial role in helping to transition Middle Eastern states in the region away from a dependence on fossil fuels—a broad goal of the Paris accords and a specific strategic goal of states like Saudi Arabia and Iran. Notwithstanding the sectarian disagreements between Iran and Saudi Arabia, both need to address their fast-growing demand for electricity; they need not be in competition with each other. Saudi Arabia currently fuels its own 10 percent annual rise in electricity needs with crude oil, owing to domestic natural dry gas reserves. Iran’s vast gas reserves could be used to meet the kingdom’s growing energy needs, but Iran’s decaying gas fields need $250 billion in major repairs. Many think that if Saudi Arabia used its investment power to revitalize Iran’s gas industry, it would secure the energy it needs to meet demands. The economic benefits of cooperation on energy could promote better relations. Another area of cooperation that can drive the local economies is the Arab Gulf’s first major cross-border enterprise, the Dolphin Gas Project, which was started in 2007. The project involves the transportation of natural gas from Qatar to Oman and to the UAE. Finally, international cooperation between Oman and Iran is developing, where Oman intends to import natural gas from Iran for industrial development. This would require investing in an underwater pipeline from the Iranian coast to Oman. The UAE could do the same to build its economy: import natural gas from Iran, since the pipelines exist. The technical know-how for all these initiatives already exists—to date the main stumbling block has been overcoming regional politics.

Qatari Oil Minister Abdullah bin Hamad al-Attiyah (L) and Dolphin Energy Chief Executive Ahmed Ali Al Sayegh hold a news conference about the inauguration of the Dolphin Energy plant in Doha May 12, 2008. Photo credit: Reuters.

In health, there is also room for mutually-beneficial cooperation. Back in 1996, the U.S. State Department’s Bureau of Near Eastern Affairs helped establish the Middle East Cancer Consortium—that effort continues to help train the next generation of scientists and medical professionals in cancer biology in the region. Other programs have focused on vaccine development for childhood diseases; preventing HIV, malaria, and tuberculosis infections; ending childhood malnutrition; and managing unwanted pregnancies. Programs like these have yielded important advances in public health and have enhanced cooperation between countries like the Palestinian Authority, Egypt, Cyprus, Turkey, and Israel with the United States.

And in a unique cross-sectoral approach, Jordan is host to a promising initiative called the Synchrotron Light for Experimental Science and Application in the Middle East (SESAME). Modeled after the European Organization for Nuclear Research (CERN), SESAME is a partnership between Bahrain, Egypt, Israel, Iran, Jordan, Pakistan, the Palestinian Authority, and Turkey that aims to create research career opportunities that will limit “brain drain” from the region and serve as a model for scientific collaboration.

STEM education: The root of science diplomacy

Science diplomacy has the potential to deliver real dividends that extend beyond the science and technology spaces themselves. When states cooperate on functional, non-politicized (or at least less politicized) issues—whether at the level of non-state scientific communities or at the level of state bureaucracies focused on energy, health, or other issues—they become more accustomed to working together and trusting each other. This can gradually have spillover effects into politics and security arenas.

Science diplomacy doesn’t just happen, though—it requires real efforts on behalf of policymakers and experts. One crucial step is advancing STEM education (science, technology, engineering, and mathematics) to build more robust and diverse expert communities. This is something that President Obama emphasized in his speech at Cairo's Al-Azhar University in 2009. He identified possible areas of cooperation, both within the region and with the United States, including researching and piloting new sources of energy, creating “green” jobs, enhancing communication and informatics, sharing medical information, generating clean water, and growing new crops. 

In some countries in the region, particularly in the Gulf, there are signs of new investment in STEM education and related efforts. For example, Qatar has pledged to spend 3 percent of its GDP on scientific research, and the United Arab Emirates (UAE) has decided to create the world’s first sustainable city. Saudi Arabia created the King Abdullah University of Science and Technology (KAUST) with a $20 billion endowment, $200 million of which has been used to attract scientists and educators from the West. Saudi Arabia, Qatar, and the UAE continue to build and sustain partnerships with European and American universities. 

Interest in science among students and the general citizenry in many Middle Eastern countries remains low, which is problematic at a time when the region’s young people need to compete in a world increasingly centered around STEM. More governments in the region—perhaps with U.S. help—need to increase efforts to attract their young people to STEM education and careers.

International cooperation on STEM issues—led by science diplomats—can strengthen relationships between Middle Eastern states and with the United States. Science and technology disciplines transcend politics, borders, and cultures, and are thus an important bridge between nations. During a time of strained geopolitical relationships, we can focus on making progress in health and disease, food and water security, and other areas—and thereby enhance domestic stability and international security in the process. 

When the Volkswagen emissions control scandal broke into the headlines in September, I wrote here how I felt like my lifelong love affair with VW had been violated. As an environmentalist, owning a Jetta that zipped along for 42 miles on a gallon of diesel was the best of both worlds. And it was a lie. My wife, Holly Flood, said she felt like she’d been “duped,” and since then she’s vowed never to buy another VW.

I’m not so sure. But I was pleased this week to see the agreed terms for the nearly half million of us who own the smaller diesel engine cars in the U.S. This was the largest car settlement in U.S. history.

What I like is the combination of individual and collective compensation for this crime.

On the individual side, if this deal is approved by the judge in early October, my family will get our 2009 Jetta TDI sedan fixed for free (if the Environmental Protection Agency approves the fix), and we’ll get a check for $5,100. Holly says that’s perfect timing for a down payment on a new car (which will not be a VW).

I’m pushing for a plug-in electric hybrid, which we can charge with renewable energy we get off the grid from our local provider, People’s Power & Light. In our case, for every electron we use, they pay to have one electron put in from wind power somewhere right here in New England. Hopefully we’ll have variable pricing of electricity by then, allowing us to charge the car when the juice is cheapest, like when the wind blows at night but few people are using much electricity.

The unknown for us is whether the VW fix will noticeably harm the performance of the car. I’m guessing it will, perhaps in its remarkable torque, in its gas mileage, or both. But at this point the car has tons of my wife’s commuting miles on it, so we’re hanging on to it as the in-town backup car. Under the settlement we could get an extra $7k and give up the car entirely. That may be tempting, as it’s at that point where it’s getting substantially more expensive to maintain, and the Kelley Blue Book value is around $6k. They apparently aren’t lowballing us.

The collective part of this agreement is actually more interesting.

VW agreed to pay $4.7 billion  into environmental programs, which in my estimation will eliminate more harm than they created. One estimate guessed that scores of premature deaths occurred in the U.S. from VW’s “defeat devices” that shut off emissions controls when they were not being tested. Most of the deaths were probably in California, where there were many more sales of diesels than elsewhere in the country. (Of course in Europe the concentration of diesels is much greater and the Guardian put the number of deaths at thousands in the U.K. alone.) 

One part of this fund will go to replace diesel buses with electric ones. This will measurably improve air quality in inner cities, the precise places where extra sooty VWs were causing ill health and premature deaths with their NOx emissions. Another part will go to install electric vehicle charging stations in California. This helps overcome the “chicken and egg” problem of people not being willing to switch to electric vehicles for fear of running out of juice. The settlement says that “Volkswagen must spend $2 billion to promote non-polluting cars (“zero emissions vehicles” or “ZEV”), over and above any amount Volkswagen previously planned to spend on such technology.” That counterfactual will probably be impossible to prove, but the idea here is fairness.

Sociologically, this is a fascinating case, because it reveals how our society resolves scandals that killed people through knowing contamination of the environment. As Deputy U.S. Attorney General Sally Yates harshly put it, "By duping regulators, Volkswagen turned nearly half a million American drivers into unwitting accomplices in an unprecedented assault on our environment." There are individuals inside this company who deserve criminal prosecution, but apparently most of the thousands of other employees did not know what was going on.

The corporate response has been interesting, and seems to vary sharply from how most U.S. auto firms have dealt with similar lawsuits and scandals in the past. VW did not drag out the battle, but set aside $16 billion immediately as a loss, and then settled rather generously with us. (This spring they had already given us a $500 gift card and $500 in repairs in what was essentially hush money.)

VW’s response to this crisis was creative, forward-looking, and ultimately pro-social. Just a week or so ago they announced that their new business model was to be in electrics: They announced they’d be rolling out 31 electric vehicles in the coming years. This is a remarkable turn for a company that pushed diesels for decades as the solution to climate change. This is what it looks like when a massive corporation whose reputation was built on trust and belief in the integrity of a brand seeks to battle its way back into a changing market.

Spending billions on charging stations and replacing diesel buses may make immediate sense—can we say if this is helping avoid premature deaths or it is merely crass self-interest? Does it matter? 

Of course it does. But my first impression of what VW did this week was of a fair deal that was not just lining my pocket. It was helping us get off fossil fuels as a society and benefiting human health and the environment in a substantial way. And by rebuilding a major employer in Germany, the U.S., and around the world into one that might be a part of the solution to climate change, this is a significant and fairly brilliant business move to position the company for the next half century.

Or am I merely a sucker for my old flame?

Renewable energy is an important source to tackle against climate change, as the latest IPCC report has pointed out. However, due to the existence of multiple market failures such as negative externalities of fossil fuels and knowledge spillovers of new technology, government subsidies are still needed to develop renewable energy, such as solar photovoltaic (PV) cells. In the United States, there have been various forms of subsidies for PV, varying from the federal level to the state level, and from the city level to the utility level. California, as the pioneer of solar PV development, has put forward the biggest state-level subsidy program for PV, the California Solar Initiative (CSI). The CSI has planned to spend around $2.2 Billion in 2007–2016 to install roughly 2 GW PV capacity, with the average subsidy level as high as $1.1/W. How to evaluate the cost-effectiveness and incentive pass-through of this program are the two major research questions we are pursing.

Our cost-effectiveness analysis is based on a constrained optimization model that we developed, where the objective is to install as much PV capacity as possible under a fixed budget constraint. Both the analytical and computational results suggest that due to a strong peer effect and the learning-by-doing effect, one can shift subsides from later periods to early periods so that the final PV installed capacity can be increased by 8.1% (or 32 MW). However, if the decision-maker has other policy objectives or constraints in mind, such as maintaining the policy certainty, then, the optimally calculated subsidy policy would look like the CSI.

As to the incentive pass-through question, we took a structural approach and in addition used the method of regression discontinuity (RD). While in general, the incentive pass-through rate depends on the curvature of the demand and supply curve and the level of market competition, our two estimations indicate that the incentive pass-through for the CSI program is almost complete. In other words, almost all of the incentive has been enjoyed by the customer, and the PV installers did not retain much. Based on the RD design, we observe that PV installers tend to consider the CSI incentive as exogenous to their pricing decision.

The relative good performance of the CSI in terms of both the cost-effectiveness and the incentive pass-through aspect are tightly related to its policy design and program management. International speaking, the biggest challenge for the design of any PV subsidy program is the quick running out of the budget, and in the end, it looks like customers are rushing for the subsidy. Such rushing behavior is a clear indication of higher-than-needed incentive levels. Due to the policy rigidity and rapid PV technological change, the PV subsidy policy may lag behind the PV cost decline; and as a result, rational customers could rush for any unnecessarily high subsidy.

Due to the high uncertainty and unpredictability of future PV costs, the CSI put forward a new design that links the incentive level change and the installed capacity goal fulfillment. Specifically, the CSI has designed nine steps to achieve its policy goal; at each step, there is a PV capacity goal that corresponds to an incentive level. Once the capacity goal is finished, the incentive level will decrease to the next lower level. Furthermore, to maintain the policy certainty, the CSI regulated that every step-wise change in the incentive level should not be higher than $0.45/W, nor smaller than $0.05/W, together with other three constraints.

A good subsidy policy not only requires flexible policy design to respond to fast-changing environment, but also demands an efficient program management system, digitalized if possible. For the CSI, the authority has contracted out a third-party to maintain a good database system for the program. Specifically, the database has documented in detail every PV system that customers requested. Key data fields include 22 important dates during the PV installation process, customers’ zip code, city, utility and county information, and various characteristics of the PV system such as price, system size, incentive, PV module and installer. All information is publicly available, which to some extent fills in the information gap held by customers and fosters the market competition among PV installers. For customers to receive the incentive, their PV systems have to pass the inspection of the local government, and also to be interconnected to the grid. On the supply side, the CSI has also certified and created a list of PV installers that every customer can choose from.

Although the CSI has ended in 2014 due to fast PV cost reduction starting from 2009, its experience has been transferred to other areas in the United States and in Europe. It is highly possible that other similar new technologies and products (e.g. the electric car and the battery) can adopt the CSI policy design, too. In summary, a good and successful policy may need to be simply, clear, credible, foreseeable, flexible, end-able, and incentive-compatible. The PV subsidy policy in China still has a long way to go when compared to the CSI.

What do Americans think about U.S. natural gas? 

The answer depends on who you ask. Presidential candidates, Washington think tank analysts, and ordinary citizens all give widely different answers to that question. In the United States, natural gas is sure to play an important role in the energy mix for the foreseeable future and has yielded several major economic, environmental, and health benefits in the short- and medium-term. Despite this, the image of natural gas has deteriorated in recent years, particularly within the environmental community. 

In a new policy brief, "Natural gas in the United States in 2016: Problem child and poster child," Tim Boersma discusses the various sentiments surrounding the debate over natural gas, analyzing the data supporting or refuting these varied points of view. Additionally, Boersma discusses the role that natural gas can play as a bridge fuel to a low-carbon economy, outlining a policy and research agenda for the utilization of natural gas going forward.

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• Natural gas in the United States in 2016