ISSN 1673-1719
CN 11-5368/P
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  30 July 2024, Volume 20 Issue 4 Previous Issue   
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Changes in Climate System
The differences of global extreme climate events changes before and after 1.5℃ overshoot   Collect
XU Ying, HAN Zhen-Yu, WU Jie, LI Rou-Ke
Climate Change Research. 2024, 20 (4): 389-402.   DOI: 10.12006/j.issn.1673-1719.2023.202
Abstract ( 186 )   HTML ( 22 )     PDF (7115KB) ( 231 )  

Based on global climate models from Coupled Model Intercomparison Projection Phase 6 (CMIP6) under SSP1-1.9 scenario, the changes in mean temperature and precipitation, as well as seven extreme climate indices, over the 23 subregions at 1.5℃level (P1 phase) and cooled to 1.5℃ level (P2 phase) were projected. Results show that the differences of temperature, precipitation, and extreme climate events between P1 and P2 phases show good agreement worldwide among multiple models, with obvious regional and local features. Multi-model consistent changes in temperature extremes generally approach or exceed 15% of the global land area. The spatial pattern of extreme cold events differences between two phases is similar to that of winter mean temperature, and the distribution of extreme hot events shows the local character. Globally, the areas with multi-model consistent increases in both cold and hot events are larger than those with the decreases. The risk of extreme cold/hot events will increase over the western part of mid-high latitudes in Eurasia, North America and northeastern China/the Tibet Plateau, eastern China, South Asia, East Africa, North America and Antarctic. Multi-model consistent changes in precipitation extremes generally exceeds 20% of global land area, but the area with increases is close to that with decreases. The spatial pattern of heavy precipitation differences is partially similar to that of annual mean precipitation: the values over southern China, South Asia, Southeast Asia, eastern and southwestern South America, North America, Australia, and central and eastern Europe will increase with good agreement, and the values over North China to northeastern China, southern edge of the Tibet Plateau, southern Africa, northern South America and northern Australia will decrease with good agreement. More consecutive dry days (CDDs) are projected in most regions, the large changes with good agreement can be found over Central Asia, South Asia, the Tibet Plateau, central and northern Russia, north of Sahara in Africa and central Africa, central Australia, parts of Antarctic. It indicates that even if global carbon emission peaks before 2030 and then begins to reduce immediately, temperature and precipitation extremes at certain regions will be even larger than those before overshooting, due to the diverse regional climate responses to global warming. Then the impact will still last many years, with the influence increasing. Thus, the projected increases in extreme climate events on regional and local scale should be alerted.

A comparative study of future summer precipitation projections in Northwest China under different physical constraint schemes   Collect
ZHOU Tian-Yi, JIANG Zhi-Hong, LI Wei, SUN Cen-Xiao
Climate Change Research. 2024, 20 (4): 403-415.   DOI: 10.12006/j.issn.1673-1719.2024.021
Abstract ( 81 )   HTML ( 15 )     PDF (5091KB) ( 114 )  

Northwest China experiences a scarcity of annual precipitation, characterized as a typical inland arid and semi-arid region. In recent years, various evidence has indicated an increasing trend in precipitation in this region. Understanding how precipitation will change in Northwest China under future warming has become a topic of widespread concern in the academic and social spheres in China. Based on two physically constrained (preferred) methods, namely, the emergent constraint and the Pareto-optimal ensemble scheme, two influential physical factors affecting summer precipitation in Northwest China were selected: tropical Indian Ocean sea surface temperature (SST) and the East Asian subtropical 200 hPa zonal wind. Different constraint schemes were applied to the summer precipitation projections from 25 CMIP6 models. The results show that, relative to the period 1995-2014, the ensemble mean of CMIP6 models projects a 23% increase in average summer precipitation in Northwest China by the end of the 21st century. The unconstrained estimation range is from -8.4% to 61.7%. After constraining with tropical Indian Ocean SST (East Asian subtropical 200 hPa zonal wind), the projected increase reaches 24% (19%), and the uncertainty range narrows to -8.4% to 52% (-9% to 45%), reducing uncertainties by 15% (21%). Further utilization of the three-variable Pareto-optimal ensemble scheme, including historical summer precipitation in Northwest China, tropical Indian Ocean SST, and East Asian subtropical 200 hPa zonal wind, indicates a 28% increase in average summer precipitation in Northwest China by the end of the 21st century, with a narrowed uncertainty range of 8% to 44%, representing a nearly 39% reduction in uncertainty. The Pareto-optimal ensemble suggests that the regions experiencing increased precipitation are concentrated in the central and western parts of Northwest China, with the maximum precipitation increase exceeding 60%.

Impacts of Climate Change
Simulated response of the ocean and land carbon cycles to positive and negative CO2 emissions   Collect
ZHANG Jing-Yu, CAO Long
Climate Change Research. 2024, 20 (4): 416-427.   DOI: 10.12006/j.issn.1673-1719.2024.058
Abstract ( 81 )   HTML ( 4 )     PDF (5422KB) ( 118 )  

Human activities lead to increase in atmospheric CO2 concentrations and global warming, threatening human survival. As a potential method to mitigate global warming, CO2 removal has garnered extensive attention in recent years. We employed the University of Victoria Earth System Climate Model (UVic ESCM) to simulate and analyze the effects of both positive and negative CO2 pulses of various intensity on the carbon cycle starting from preindustrial equilibrium (CO2 concentration: 285×10-6). The results show that in the 100 Pg C positive CO2 pulse emission scenario, 100 (1000) years after imposing the CO2 pulse, only 28% (18%) of the CO2 emission remains in the atmosphere, the ocean absorbs about 38% (61%) of the CO2 emission, the land absorbs about 34% (21%) of the CO2 emission. In the 100 Pg C negative CO2 pulse emission scenario, the ocean and the land releases CO2 to the atmosphere, weakening the effect of CO2 removal. 100 (1000) years after imposing the CO2 pulse, only 23% (12%) of the initial CO2 removal from the atmosphere remains, with 36% (65%) offset by ocean carbon release, 41% (23%) offset by land carbon release. According to different positive and negative pulse scenarios, the cumulative airborne fraction in the positive pulse scenario is always higher than cumulative removal fraction in the negative pulse scenario of the same intensity, which indicates that the positive and negative pulse carbon emission scenario responses of the sea and land carbon cycles are asymmetric. It means that negative emissions of higher intensities are needed to offset the atmospheric CO2 concentration increases caused by positive emissions.

Research on the impact of climate risk on product prices in futures market   Collect
WANG Qian, GUO Fu
Climate Change Research. 2024, 20 (4): 428-439.   DOI: 10.12006/j.issn.1673-1719.2024.043
Abstract ( 155 )   HTML ( 9 )     PDF (2232KB) ( 163 )  

Based on the basic theory of the impact of climate risk on product prices in futures market and the combination of text analysis and GARCH model, the impacts of climate risk on product prices in futures market were quantitatively evaluated by taking four kinds of macroeconomic factors into account. The results show that, the climate risk index has a positive correlation with the price index of energy and chemical futures, and climate risk has risk spillover effect on both energy futures and chemical futures markets. The current climate risk index has a significant positive impact on the yield of agricultural, energy and chemical futures price index, and a significant negative impact on the yield of grain futures price index. The current climate risk index has a significant positive impact on the yield volatility of agricultural futures price index, and a significant negative impact on the yield volatility of grain, chemical and energy futures price index. The research results reveal the complex impact of climate risks on futures markets and help provide scientific basis for financial markets to cope with climate risks.

Mitigation to Climate Change
Digital economy empowers “Dual Carbon” goals: influence mechanism and implementation path   Collect
LIU Li-Wen, WANG Mou
Climate Change Research. 2024, 20 (4): 440-453.   DOI: 10.12006/j.issn.1673-1719.2024.067
Abstract ( 70 )   HTML ( 8 )     PDF (1495KB) ( 93 )  

The impact of carbon emissions is global, posing a threat to global climate, ecological balance, human health and other aspects. Digital economy is being integrated into various fields of economic and social development, and its impact on carbon emissions deserves attention and exploration. In order to verify the complex internal influence path between digital economy and carbon emissions, this study successively adopts the two-way fixed effects model with time and individual effects, the mediation model, the threshold effect model and the spatial Durbin model. The empirical results show that: first, digital economy can significantly inhibit carbon emission intensity and per capita carbon emissions; Second, the digital economy can help adjust the energy structure, thus significantly reducing carbon emissions. Third, with the improvement of energy efficiency, digital economy and carbon emissions show an inverted U-shaped relationship. Fourthly, under three spatial weight matrices, the effects of digital economy on carbon emission show spatial spillover effect. The conclusions of this study provide reference for further promoting the development of digital economy and realizing China’s “Dual Carbon” goals.

Study on the decarbonization path of Chinese civil aviation based on a system dynamic model   Collect
TIAN Li-Jun, XU Sen-Yu
Climate Change Research. 2024, 20 (4): 454-464.   DOI: 10.12006/j.issn.1673-1719.2024.071
Abstract ( 99 )   HTML ( 6 )     PDF (1626KB) ( 113 )  

Carbon emission reduction in the civil aviation industry is a complex issue involving economic, social, technological and environmental aspects. The implementation of pathway simulation based on a systems approach will help to optimize the sustainable plan for Chinese civil aviation industry. To quantitatively identify the carbon reduction effects and costs, a system dynamics (SD) model based on civil aviation decarbonization was developed, with full consideration of elemental and sub-system compositions, and scenarios were simulated and explored to determine the effects of the carbon reduction pathways and implementation costs of the civil aviation industry. The results showed that the single policy simulation scenarios of the industry’s implementation of energy-saving technology advancement, alternative fuel application, promotion of new power energy, carbon offset mechanism and high-speed rail substitution cannot achieve the industry’s carbon-neutral long-term development goal. The combination policy of multiple measures provided the optimal comprehensive decarbonization program for the industry’s decarbonization development. In the future, the industry should actively promote the large-scale application of sustainable aviation fuel (SAF) in the short term, increase the research and development of hydrogen, electricity and hybrid aircraft in the medium term, actively adopt integrated transportation modes such as high-speed rail substitution, and continue to improve the energy-saving and emission-reduction technologies of the industry in the long term, as well as promote the incorporation of the civil aviation industry into the national carbon market. The results of the study can provide a reference for policy formulation for the sustainable development of the civil aviation sector, and help the industry decarbonize deeply.

Adaptation to Climate Change
Research on the path of transition finance legal system of China under the background of addressing climate change   Collect
PAN Xiao-Bin, LIU Shang-Wen
Climate Change Research. 2024, 20 (4): 465-474.   DOI: 10.12006/j.issn.1673-1719.2023.217
Abstract ( 52 )   HTML ( 5 )     PDF (1494KB) ( 49 )  

Transition finance plays an important role in supporting the green transformation of high-carbon enterprises and coping with climate change. As an important and emerging financial field, exploring its legalization path can provide an important reference for the construction of China’s transition finance system. By combing the emergence and development of transition finance, and drawing on the legislative experience of the European Union in the field of transition finance, the legalization path of the legal system of transition finance is discussed in the light of China’s actual situation. Considering the legislative practice, policy status quo, market practice experience and legislative cost, it is more appropriate to incorporate the legal system of transition finance into the legal system of green finance. In terms of legislative path, China should introduce the principle clauses of transition finance into the general provisions and sub-provisions of the Green Finance Law, and complement it with the implementation of low-ranking legislation on transition finance. In terms of institutional arrangements, we should clarify the catalog of supportive financial activities, the mechanism for auditing and disclosure of transformational activities, the legal liability system and other supporting systems through multi-level legislation, and think about the synergistic paths of transformational finance laws and policy systems.

Value accounting and evaluation of gross climate ecosystem product in Anji county, Zhejiang province   Collect
ZHAI Xiao-Yao, WANG Kuo, LI Zheng-Quan, SONG Chao-Hui, FANG He, YAO Xia, ZHANG Han, YU Zhen-Yan, XU Chan-Chan
Climate Change Research. 2024, 20 (4): 475-484.   DOI: 10.12006/j.issn.1673-1719.2023.190
Abstract ( 98 )   HTML ( 3 )     PDF (1747KB) ( 166 )  

Taking Aniji county of Zhejiang province as a case study, an evaluation index system was constructed, and the economic value and functional quantity of gross climate ecosystem product were calculated from four categories: climate resources exploitation value, climate regulation service value, climate carbon fixation and oxygen release value, and climate brand added value. The total value of gross climate ecosystem product of Anji in 2022 was CNY 25.908 billion, accounting for 44.49% of its GDP (CNY 58.237 billion). Of which, climate resources exploitation value was CNY 1.335 billion, accounting for 5.15%; climate regulation service value was CNY 16.711 billion, accounting for 64.50%; climate carbon fixation and oxygen release value was CNY 3.388 billion, accounting for 13.08%; climate brand added value was CNY 4.474 billion, accounting for 17.27%. The total potential value of water resources, wind resources and solar resources was 28.143 billion kW?h, with a total value of CNY 14.152 billion. The results show that the accounting of gross output value of climate ecosystems can monetize the state and changes of Anji’s climate ecosystems, and provide evaluation reference for local green development planning and climate change adaptation.

Notes
Understanding climate change and land-atmosphere interactions in cold regions: a brief overview of Professor Zhang Tingjun’s academic contributions   Collect
WANG Kang, MU Cui-Cui, LIU Jia, PENG Xiao-Qing, CAO Bin, ZHENG Lei
Climate Change Research. 2024, 20 (4): 485-491.   DOI: 10.12006/j.issn.1673-1719.2024.016
Abstract ( 66 )   HTML ( 7 )     PDF (7426KB) ( 103 )  
National and provincial population projection databases under Shared Socioeconomic Pathways (SSP1-5) v2   Collect
GUO Huan-Huan, JING Cheng, JIANG Tong, SU Bu-Da, WANG Yan-Jun, YANG Yu-Ming
Climate Change Research. 2024, 20 (4): 492-497.   DOI: 10.12006/j.issn.1673-1719.2024.086
Abstract ( 153 )   HTML ( 10 )     PDF (2656KB) ( 93 )  
National and provincial economy projection databases under Shared Socioeconomic Pathways (SSP1−5)_v2   Collect
YANG Yu-Ming, ZHAI Jian-Qing, SU Bu-Da, JING Cheng, JIANG Tong, GUO Huan-Huan
Climate Change Research. 2024, 20 (4): 498-503.   DOI: 10.12006/j.issn.1673-1719.2024.085
Abstract ( 101 )   HTML ( 12 )     PDF (2211KB) ( 167 )  
Global warming and cities   Collect
ZHAO Zong-Ci, LUO Yong, HUANG Jian-Bin
Climate Change Research. 2024, 20 (4): 504-508.   DOI: 10.12006/j.issn.1673-1719.2024.136
Abstract ( 88 )   HTML ( 13 )     PDF (1042KB) ( 110 )  
2024
Vol.20
No.3 
2024-05-30
pp.0-388
No.2
2024-03-30
pp.0-264
No.1
2024-01-30
pp.0-128
2023
Vol.19
No.6 
2023-11-30
pp.683-826
No.5
2023-09-30
pp.0-682
No.4
2023-07-30
pp.0-540
No.3
2023-05-30
pp.0-402
No.2
2023-03-30
pp.133-262
No.1
2023-01-30
pp.0-132
2022
Vol.18
No.6 
2022-11-30
pp.653-800
No.5
2022-09-30
pp.523-652
No.4
2022-07-30
pp.389-522
No.3
2022-05-30
pp.261-388
No.2
2022-03-30
pp.129-260
No.1
2022-01-30
pp.0-128
2021
Vol.17
No.6 
2021-11-30
pp.629-754
No.5
2021-09-30
pp.503-628
No.4
2021-07-30
pp.379-502
No.3
2021-05-30
pp.254-378
No.2
2021-03-30
pp.131-254
No.1
2021-01-30
pp.1-130
2020
Vol.16
No.6 
2020-11-30
pp.657-774
No.5
2020-09-30
pp.535-656
No.4
2020-07-30
pp.395-534
No.3
2020-05-30
pp.263-394
No.2
2020-03-30
pp.133-262
No.1
2020-01-30
pp.1-132
2019
Vol.15
No.6 
2019-11-30
pp.575-708
No.5
2019-09-30
pp.445-574
No.4
2019-07-30
pp.335-444
No.3
2019-05-30
pp.217-334
No.2
2019-03-30
pp.107-216
No.1
2019-01-30
pp.1-106
2018
Vol.14
No.6 
2018-11-30
pp.547-648
No.5
2018-09-30
pp.437-546
No.4
2018-07-30
pp.331-436
No.3
2018-05-31
pp.221-330
No.2
2018-03-30
pp.111-220
No.1
2018-01-31
pp.1-110
2017
Vol.13
No.6 
2017-11-30
pp.517-630
No.5
2017-09-30
pp.407-516
No.4
2017-07-30
pp.0-0
No.3
2017-05-30
pp.0-0
No.2
2017-03-30
pp.0-0
No.1
2017-01-30
pp.1-94
2016
Vol.12
No.6 
2016-11-30
pp.467-574
No.5
2016-09-30
pp.355-466
No.4
2016-07-30
pp.261-354
No.3
2016-05-31
pp.0-0
No.2
2016-03-30
pp.0-0
No.1
2016-01-30
pp.0-0
2015
Vol.11
No.6 
2015-11-30
pp.379-446
No.5
2015-09-30
pp.301-378
No.4
2015-07-31
pp.0-0
No.3
2015-05-31
pp.157-230
No.2
2015-03-30
pp.79-156
No.1
2015-01-30
pp.1-78
2014
Vol.10
No.6 
2014-11-30
pp.391-470
No.5
2014-09-30
pp.313-390
No.4
2014-07-30
pp.235-312
No.3
2014-05-30
pp.0-0
No.2
2014-03-30
pp.79-156
No.1
2014-01-31
pp.1-78
2013
Vol.9
No.6 
2013-11-30
pp.391-452
No.5
2013-09-30
pp.313-390
No.4
2013-07-30
pp.235-312
No.3
2013-05-30
pp.157-234
No.2
2013-03-30
pp.79-156
No.1
2013-01-31
pp.1-78
2012
Vol.8
No.6 
2012-11-30
pp.391-476
No.5
2012-09-30
pp.313-390
No.4
2012-07-30
pp.235-312
No.3
2012-05-30
pp.157-234
No.2
2012-03-30
pp.79-156
No.1
2012-01-30
pp.1-78
2011
Vol.7
No.6 
2011-11-30
pp.385-460
No.5
2011-09-30
pp.307-384
No.4
2011-07-30
pp.235-306
No.3
2011-05-30
pp.0-0
No.2
2011-03-30
pp.79-156
No.1
2011-01-30
pp.1-78


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For Selected: Toggle Thumbnails
Effects of drought and waterlogging stress on root-shoot ratio and source-sink relationship of grain filling of summer maize
ZHAO Hua-Rong, ZHANG Ling, QI Yue, YANG Chao, HU Li-Li
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.115
Accepted: 04 September 2024

Low Emissions Analysis Platform (LEAP): applications and challenges in addressing climate change
WU Pei-Ze, CHEN Sha , LIU Ying-Ying , LI Xiao-Tong, DU Zhan-Xia, CUI Shu-Fen, JIANG Ke-Jun
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.145
Accepted: 04 September 2024

Changes in lakes in the southwest part of Nagqu, Tibet and their response to climate change in the past 50 years
Deji-Yuzhen, Lhaba, Basang-Wangdui, Baima-Yucuo, Danzeng-Yiga, Pingcuo-Wangdan, Deji-Yangzong
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.106
Accepted: 04 September 2024

Medium and long term power resource planning considering the coupled impact of climate risks
YUAN Jia-Hai, MOU Qi-Lin, ZHANG Hao-Nan, ZHAO Yi-Ying, ZHANG Jian
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.129
Accepted: 04 September 2024

Progress in the study on the interaction between proglacial lake and lake-terminating glacier over the Qinghai-Tibet Plateau
CHE Yan-Jun, CHEN Li-Hua, WU Jia-Kang , GU Lai-Lei, Wu Rong, ZHANG Dong-Qi, DING Ming-Hu
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.074
Accepted: 28 August 2024

The impact of climate policy uncertainty on the green innovation of enterprises
ZHANG Na, SUN Yan-Yu, ZHAO Xiao-Jun, CHANG Si-Chun, WU li-Yan
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.107
Accepted: 28 August 2024

An overview and the outlook for wetland ecosystems in the Qinghai-Tibetan Plateau under Climate Changes
NIU Zhen-Guo, JING Yu-Hang, ZHANG Dong-Qi, ZHANG Bo
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.083
Accepted: 28 August 2024

Analysis of hourly precipitation variations in autumn in West China
WU Yao, TANG Hong-Yu, WEI Lin-Xiao, HE Hui-Gen
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.062
Accepted: 28 August 2024

Trends of precipitation and characteristics of wetness-dryness encountering in the water source and receiving areas of the west route of the South-to-North Water Transfer Project
WANG Rong, DU Xiao-Zhong, CHAO Qing-Chen, ZHAO Shan-Shan, YE Dian-Xiu, LI Xiu-Cang, LI Ying, ZHANG Meng-Ran
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.131
Accepted: 28 August 2024

Spatio-temporal variation of vapor pressure deficit and impact factors in the Yalung Zangbo River basin from 1981 to 2023
DU Jun, GAO Jia-Jia, CHEN Tao, Tsewang, Pakgordolma
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.097
Accepted: 28 August 2024

Research on China’s methane emission reduction path based on SPAMC-Methane model
XIE Rui-Li, CHAI Qi-Min
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2024.044
Accepted: 16 August 2024

Global Methane emission status and characteristics based on greenhouse gas inventory in UNFCCC Annex I countries
GAO Wen-Kang, HU Jie, MA Zhan-Yun, GAO Dong, LIU Shu-Le, LI Zhao-Meng, YAN Wei, GENG Jin-Ze, GAO Qing-Xian
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2023.119
Accepted: 28 February 2024

Study of evaluation method on the climate of extreme high temperatures based on dynamic return periods
null
Climate Change Research   
Accepted: 07 September 2022

Analysis on the Key Findings Related to Emission Trends and Drivers from the Working Group Ⅲ Contribution to the IPCC Sixth Assessment Report
TAN Xian-Chun, DAI Han-Cheng, GU Bai-He, HUANG Chen, ZHU Kai-Wei, MA Xiao-Tian, YAN Hong-Shuo, LIU Xin-Yuan, ZHU Yan-Lei
Climate Change Research    doi: 10.12006/j.issn.1673-1719.2022.153
Accepted: 24 August 2022

Study on the benchmark method for national carbon trading in China’s iron and steel industry
TAN Qi-Lu, LIU Lan-Ting, ZHU Song-Li
Climate Change Research   
Accepted: 06 September 2021

Study on the greenhouse gas emissions information disclosure system
LIU Hai-Yan, ZHENG Shuang
Climate Change Research   
Accepted: 27 August 2021

Evaluation of extreme precipitation indices performance based on NEX-GDDP downscaling data over China
WANG Qian-Zhi, LIU Kai, WANG Ming
Climate Change Research   
Accepted: 27 August 2021


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