Abstract
Solar photovoltaic (PV) electricity generation can greatly reduce both air pollutant and greenhouse gas emissions compared to fossil fuel electricity generation. The Chinese government plans to greatly scale up solar PV installation between now and 2030. However, different PV development pathways will influence the range of air quality and climate benefits. Benefits depend on how much electricity generated from PV is integrated into power grids and the type of power plant displaced. Using a coal-intensive power sector projection as the base case, we estimate the climate, air quality, and related human health benefits of various 2030 PV deployment scenarios. We use the 2030 government goal of 400 GW installed capacity but vary the location of PV installation and the extent of inter-provincial PV electricity transmission. We find that deploying distributed PV in the east with inter-provincial transmission maximizes potential CO2 reductions and air quality-related health benefits (4.2% and 1.2% decrease in national total CO2 emissions and air pollution-related premature deaths compared to the base case, respectively). Deployment in the east with inter-provincial transmission results in the largest benefits because it maximizes displacement of the dirtiest coal-fired power plants and minimizes PV curtailment, which is more likely to occur without inter-provincial transmission. We further find that the maximum co-benefits achieved with deploying PV in the east and enabling inter-provincial transmission are robust under various maximum PV penetration levels in both provincial and regional grids. We find large potential benefits of policies that encourage distributed PV deployment and facilitate inter-provincial PV electricity transmission in China.
Highlights
At Belfer Center for Science and International Affairs, Harvard Kennedy School, Princeton, NJ 08544, United States of America
We further calculate PV capacity factors to measure PV efficiency
The model takes input of surface solar irradiance, first calculates the point-of-arrayirradiance (POAI, irradiance received by a panel at any tilted angle), further takes the input of weather data to calculate the direct-current (DC) output power, and applying the inverter for the alternating current (AC) output power
Summary
Is the effective emission factor for the specific category of coal-fired power plant j in province i (unit: kt/PJ). Is the NO emission factor for the specific type of coal-fired power plant j in province i (unit: kt/PJ). Coal-fired power plants in GAINS are divided into 18 different categories based on their efficiency levels and air pollutant emission factors (unit: g/kWh electricity generated). The. ECLIPSE_v5a_CLE scenario does not have a plant-level database of all coal-fired power plants, only the aggregated electricity generation data in each category is provided in the GAINS model. We use the same methods for emissions outside China, where we map the annual country-specific emissions in ECLIPSE_v5a_CLE onto gridded (0.1 degree by 0.1 degree) monthly profiles following the spatial and temporal patterns from the HTAP emission inventory
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