Natural gas could possibly become a significant portion of the future fuel mix in China. However, there is still great uncertainty surrounding the size of this potential market and therefore its impact on the global gas trade. In order to identify some of the important factors that might drive natural gas consumption in key demand areas in China, we focus on three regions: Beijing, Guangdong, and Shanghai. Using the economic optimization model MARKAL, we initially assume that the drivers are government mandates of emissions standards, reform of the Chinese financial structure, the price and available supply of natural gas, and the rate of penetration of advanced power generating and end-use. The results from the model show that the level of natural gas consumption is most sensitive to policy scenarios, which strictly limit SO2 emissions from power plants. The model also revealed that the low cost of capital for power plants in China boosts the economic viability of capital-intensive coal-fired plants. This suggests that reform within the financial sector could be a lever for encouraging increased natural gas use.

Carbon Capture and Storage (CCS) technologies form a key piece of virtually all roadmaps for global carbon dioxide (CO₂) emissions reductions-many studies predict that CCS will contribute 20-50% of the necessary CO₂ emissions reductions by 2100. To assess actual progress of CCS projects towards fulfilling these expectations, the PESD Carbon Storage Project Database tracks all publicly announced CCS projects worldwide.

Through careful examination of numerous information sources, we grouped all CCS projects into three categories according to the probability of their completion: currently operating (100% likelihood), possible (estimated 50-90% likelihood), and speculative (estimated 0-50% likelihood).

We find that even under the aggressive scenario that all "possible" projects are indeed realized, this will result in about 80 Mt CO₂/yr of reductions worldwide by 2025, far short of the 350 Mt CO₂/yr of reductions that are projected as technologically feasible using CCS by 2030 in the US alone.

Looking worldwide, then, total carbon storage activity might need to be on the order of 1 billion tonnes CO₂/yr just for carbon storage to play a big role as one of a portfolio of technologies deployed so that the overall energy system cuts emissions on a path consistent with 500-550ppm. Our study shows that the actual deployment plans are on track to deliver less than 1% of what's needed.

We've then gone a step further and looked at the design of each carbon storage project in our database. We find that the vast majority of the most likely projects are associated with Enhanced Oil Recovery (EOR), sweetening of natural gas, and the production of synthetic natural gas (SNG). That is, the most interesting niche financially is associated with making more fossil fuels. While that investment pattern is understandable, it has huge implications for carbon storage in the power sector (which is where everyone thinks carbon capture and storage, or "CCS", is very attractive for cutting emissions) for the simple reason that only a tiny fraction of carbon storage investment plans envisions the use of CCS at scale. Our guess is that carbon storage will be developed through niche markets in EOR and SNG and then spread, perhaps, to CCS. But that pathway will be slow to unfold and suggests that visions of large scale near-term CCS will be hard to materialize without much greater investment in developing the technologies.

The second version of the PESD Carbon Storage Project Database, developed by PESD researchers Varun Rai, Ngai-Chi Chung, Mark C. Thurber, and David G. Victor, was released on 12 November 2008. The previous version was released on 30 June 2008.

Based on an analysis of a rural household survey data in Hubei province in 2004, we explore patterns of residential fuel use within the conceptual framework of fuel switching using statistical approaches.

Cross sectional data show that the transition from biomass to modern commercial sources is still at an early stage, incomes may have to rise substantially in order for absolute biomass use to fall, and residential fuel use varies tremendously across geographic regions due to disparities in availability of different energy sources. Regression analysis using logistic and tobit models suggest that income, fuel prices, demographic characteristics, and topography have significant effects on fuel switching. Moreover, while switching is occurring, the commercial energy source which appears to be the principal substitute for biomass in rural households is coal. Given that burning coal in the household is a major contributor to general air pollution in China and to negative health outcomes due to indoor air pollution, further transition to modern and clean fuels such as biogas, LPG, natural gas and electricity is important. Further income growth induced by New Countryside Construction and improvement of modern and clean energy accessibility will play a critical role in the switching process.

Google's initiative RE < C seeks to develop sources of renewable energy that are cheaper than coal-fired power. David G. Victor speaks to an audience at Google's Mountain View, CA headquarters about the current status and future prospects for coal -- the right hand side of Google's equation. 

As oil prices surge through $140/barrel at the time of writing, surely one can at least count on the invisible hand of the market to drive further exploration and production and ultimately bring more supplies on line, right? Or perhaps, more ominously, high oil prices presage a darker future of shortage and conflict as global oil fields pass their geological “peak”? In fact, both positions miss a crucial point about the dynamics of the world oil market — that it is increasingly animated by the counterintuitive behavior of the state-owned oil and gas giants that now control the vast majority of the world’s hydrocarbon resources.

“On average national oil companies (NOCs) extract resources at a far lower rate than international oil companies (IOCs), leaving about 700 billion barrels of oil effectively ‘dead’ to the world market.”So-called “national oil companies,” or NOCs, own about 80 percent of the world’s proven reserves of oil, a percentage that has been on the rise as the persistent high price environment encourages countries to assert even tighter control over the rent streams flowing from their resources. NOCs are curious and variegated beasts, and, contrary to the popular imagination, some are highly capable both technically and organizationally. Brazil’s Petrobras is an acknowledged world leader in deepwater drilling, while Norway’s StatoilHydro is highly regarded for its competence and transparent business practices. Saudi Arabia’s national champion, SaudiAramco, is secretive to the outside world but generally considered to be a well-run, technically capable organization. At the other end of the continuum, government infighting and micromanagement hobble Mexico’s Pemex and Kuwait’s KPC. Once-independent PDVSA in Venezuela has been remade by President Hugo Chávez into a government puppet that spends liberally on social programs but consistently undershoots its production targets. And indeed some national oil companies are hardly oil companies at all — Nigeria’s NNPC, for example, is mostly a rent-seeking bureaucracy.

What NOCs do share in common as distinct from the familiar international oil companies (IOCs) is being answerable to a host government, which inevitably brings with it some focus on objectives other than simple profit maximization. Typically, an NOC arises originally from the desire of resource-rich governments (“principals”) to gain more effective control over resource extractors (“agents”) by creating an oil champion owned by the state. Prior to NOC formation, governments are frequently (and often justifiably) wary of exploitation by the foreign oil operators providing hydrocarbon extraction services. Lacking a deep understanding of the costs of production, states are simply unable to be sure they are taxing their agents appropriately. In addition to enhancing control over the hydrocarbon sector and the revenue it brings, states may hope for other benefits from the NOC: cheap energy to fuel a growing economy, employment and development of local industry to support the hydrocarbon sector, or even foreign policy leverage derived from control of key resources.

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A detailed study of NOC performance and strategy at the Program on Energy and Sustainable Development at FSI suggests a useful way of thinking about the effects of NOC resource domination on world oil and gas markets. Price versus quantity supply curves from classical economics assume that increased price will spur efforts to expand supply. Unfortunately, the counterintuitive reality for NOCs is that, when it comes to expanding supply in the current high-price environment, most either 1) can but don’t want to or 2) want to but can’t. The end result is what one could call a “backward-bending” supply curve — additional price increases do little or nothing to boost supply.

“The world has plentiful hydrocarbons in the ground, but that’s where many of them are going to stay due to the unique organizational and political dynamics of the NOCs.”In the “can but don’t want to” category are resourcerich governments that have decided they cannot assimilate any more money. Already, their investments are running into political resistance around the globe — witness Dubai’s failed attempt to purchase U.S. port management contracts, CNOOC’s failed bid for Unocal, or the increasing calls for curbs on the activities of sovereign wealth funds. Nations may decide they have enough cash and are better off leaving resources in the ground where they safely await monetization at a later date.

In the “want to but can’t” camp are countries and their NOCs that are simply unable to provide the stable political and regulatory climate to support additional build-out of expensive production and transport infrastructure. This situation is particularly common for natural gas, where long investor time horizons are needed to bankroll the multibilliondollar capital costs of pipelines or liquefied natural gas (LNG) terminals.

Meanwhile, international oil companies are left on the sidelines salivating helplessly over the vast reserves in NOC hands. Venezuela’s Orinoco region could yield hundreds of billions of barrels of heavy crude, but the government and a nowpliant PDVSA invite favored countries and their NOCs to explore rather than selecting the operators most capable of extracting the challenging but plentiful resource. Technical expertise and massive investment are required to fully develop vast Russian gas fields including Kovykta, Shtokman, and Yamal, but IOCs already burned by nationalizations and shifting rules in these and other Russian ventures are unlikely to be in a position to supply enough of either. In the face of dwindling resources they can tap, IOCs will need to diversify their business models, perhaps tackling technologically challenging options like oil sands or liquids from coal in conjunction with the carbon storage techniques that could make these palatable from a climate change perspective. Ironically, the only “easy” oil for IOCs has become oil that is geologically and technologically difficult.

While oil price is dependent on many factors (including global economic health) and is impossible to forecast with certainty, one can confidently predict continued tight supply of oil and gas, especially given global demand that will be propped up indefinitely by rising consumption in China and India. The world has plentiful hydrocarbons in the ground, but that’s where many of them are going to stay due to the unique organizational and political dynamics of the NOCs. Leverage over the market is weak; measures to reduce demand for oil and gas (though politically unpopular) or to spur development of alternative fuels and associated infrastructure (though slow to develop at scale) may be all that we have.