Energy Transition

ASK MIT CLIMATE: If the U.S. limits fossil fuel production at home, will we turn to cleaner sources of energy, or just import more oil and gas?

Sustained growth of sulfur hexafluoride emissions in China inferred from atmospheric observations

Abstract: Sulfur hexafluoride (SF₆) is a potent greenhouse gas. Here we use long-term atmospheric observations to determine SF₆ emissions from China between 2011 and 2021, which are used to evaluate the Chinese national SF₆ emission inventory and to better understand the global SF₆ budget. SF₆ emissions in China substantially increased from 2.6 (2.3-2.7, 68% uncertainty) Gg yr⁻¹ in 2011 to 5.1 (4.8-5.4) Gg yr⁻¹ in 2021.

The increase from China is larger than the global total emissions rise, implying that it has offset falling emissions from other countries. Emissions in the less-populated western regions of China, which have potentially not been well quantified in previous measurement-based estimates, contribute significantly to the national SF₆ emissions, likely due to substantial power generation and transmission in that area. The CO₂-eq emissions of SF₆ in China in 2021 were 125 (117-132) million tonnes (Mt), comparable to the national total CO₂ emissions of several countries such as the Netherlands or Nigeria.

The increasing SF₆ emissions offset some of the CO₂ reductions achieved through transitioning to renewable energy in the power industry, and might hinder progress towards achieving China’s goal of carbon neutrality by 2060 if no concrete control measures are implemented.

2023 Annual Report of the MIT Joint Program

EPA says it's 'looking into' study that found electric cars are MORE toxic than gas-powered vehicles

Assessing Compounding Climate-Related Stresses and Development Pathways on the Power Sector in the Central U.S.

Abstract: Future configurations of the power system in the central region of the U.S. are dependent on relative costs of alternative power generation technologies, energy and environmental policies, and multiple climate-induced stresses. Higher demand in the summer months combined with compounding supply shocks in several power generation technologies can potentially cause a “perfect storm” leading to failure of the power system. Potential future climate stress must be incorporated in investment
decisions and energy system planning and operation.

We assess how projected future climate impacts on the power system would affect alternative pathways for the electricity sector considering a broad range of generation technologies and changes in demand. We calculate a “potential supply gap” metric for each pathway, system component, and sub-region of the U.S. Heartland due to climate-induced effects on electricity demand and power generation. Potential supply gaps range from 5% in the North Central region under mild changes in climate to 21% in the Lakes-Mid Atlantic region under more severe climate change.

We find increases in electricity demand to be more important in determining the size of the potential supply gap than stresses on power generation, while larger shares of renewables in the power system contribute to lower supply gaps. Our results provide a first step toward considering systemic climate impacts that may require changes in managing the grid or on potential additional capacity/reserves that may be needed.

Why hydrogen is losing the race to power cleaner cars

Explained: Carbon credits