Constrained future brightening of solar radiation in China and its implication for the solar power
This study is led by Prof. Kun Yang (Department of Earth System Science, Tsinghua University). Surface solar radiation (Rs) data is the essential information for the development of solar power usage to mitigate the ongoing climate change. To meet China’s carbon neutrality goal, China has invested and planned heavily in the solar photovoltaic systems. However, future projections of Rs based on climate models contain large uncertainties due to internal climate variability, model uncertainty, and scenario uncertainty, which have not been eliminated by previous studies. Moreover, the model biases in Rs and the underlying drivers have yet to be quantified.
By integrating the high-quality observations and the latest Coupled Model Intercomparison Project Phase 6 (CMIP6) model data of Rs, the research team explored the model bias of CMIP6 models in Rs and quantified the physical causes of the model bias in China. The systematic bias in Rs in CMIP6 models is revealed to be caused by clouds and aerosols, resulting in largely uncertain projections for future changes in Rs (No.1).
To correct this effect, the team used historical biases of models to constrain the future projections of Rs under three possible future scenarios based on emergent constraints, an approach with a solid physical basis for narrowing the uncertainties of future climate projections through the combination of an ensemble of climate simulations with contemporary measurements. The constrained results substantially reduce the projection uncertainties by about 56% in the mid-21st century (No.2). Moreover, they found that the constraints using the combined effect of the TCC and Rs-clear biases can account for about 81% of the projection uncertainties using R.
Moreover, the constrained projections of Rs show a spatial pattern significantly favorable for the future solar energy layout. They found that the mean Rs change during 2050-2069 relative to 1995-2014 is brightening. Particularly in North China and Southeast China with higher power demand, the constrained projections present more significant brightening (No.3).
With increased anthropogenic forcing, the constrained future changes become weaker brightening in eastern China and more dimming in western China (No.3). “Low anthropogenic emissions under the carbon neutrality actions would not only help to mitigate global warming but also increase solar energy potential, consequently creating positive feedback for building a climate-resilient society”, Yang says.
Better estimates and uncertainties of future Rs changes improves the reliability of climate projections to facilitate effective investment of solar power in China. Their results highlight the need to consider the change in spatial pattern of future Rs when making policies or decisions associated with future solar energy deployment.
(a) The relationship between the future Rs during 2050-2069 in SSP1-2.6 (a low-emission scenario) and the historical bias in Rs during 1961-2014 for the 24 models. (b) Comparisons of raw and constrained projections of Rs in SSP1-2.6. Rs projections are constrained by the historical bias in Rs (red bars) and the historical bias in TCC and Rs-clear, respectively (blue bars). Photo credit: Yanyi He and Kun Yang.
Future changes (shading; in W•m-2) in the 20-year mean of Rs during 2050-2069 relative to the 1995-2014 mean from constrained values in three possible future scenarios, i.e., SSP1-2.6 (a), SSP2-4.5 (b) and SSP5-8.5 (c), with the 66% confidence interval shown as contour. Photo credit: Yanyi He and Kun Yang.
CREDIT
©Science China Pressicle:
Constrained future brightening of solar radiation and its implication for China's solar power
https://doi.org/10.1093/nsr/nwac242
JOURNAL
National Science Review
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