1. Haines A, Amann M, Borgford-Parnell N, Leonard S, Kuylenstierna J, Shindell D. Short-lived climate pollutant mitigation and the Sustainable Development Goals. Nature Climate Change. 2017;7(12):863-9.
2. Baker LH, Collins WJ, Olivié DJL, Cherian R, Hodnebrog Ø, Myhre G, et al. Climate responses to anthropogenic emissions of short-lived climate pollutants. Atmos Chem Phys. 2015;15(14):8201-16.
3. Stohl A, Aamaas B, Amann M, Baker LH, Bellouin N, Berntsen TK, et al. Evaluating the climate and air quality impacts of short-lived pollutants. Atmospheric Chemistry and Physics. 2015;15(18):10529-66.
4. Apte JS, Marshall JD, Cohen AJ, Brauer M. Addressing global mortality from ambient PM2. 5. Environmental science & technology. 2015;49(13):8057-66.
5. Butt E, Turnock S, Rigby R, Reddington C, Yoshioka M, Johnson J, et al. Global and regional trends in particulate air pollution and attributable health burden over the past 50 years. Environmental Research Letters. 2017;12(10):104017.
6. Friedlingstein P, O'sullivan M, Jones MW, Andrew RM, Hauck J, Olsen A, et al. Global carbon budget 2020. Earth System Science Data. 2020;12(4):3269-340.
7. Saunois M, Stavert AR, Poulter B, Bousquet P, Canadell JG, Jackson RB, et al. The global methane budget 2000–2017. Earth System Science Data. 2020;12(3):1561-623.
8. Silver B, Reddington CL, Arnold SR, Spracklen DV. Substantial changes in air pollution across China during 2015–2017. Environmental Research Letters. 2018 2018/11/13;13(11):114012.
9. MEE. Guiding Opinion on Coordinating and Strengthening the Work Related to Climate Change and Environmental Protection. Ministry of Ecology and Environment 2021:http://www.mee.gov.cn/xxgk2018/xxgk/xxgk03/202101/t20210113_817221.html.
10. Ramanathan V, Feng Y. Air pollution, greenhouse gases and climate change: Global and regional perspectives. Atmospheric environment. 2009;43(1):37-50.
11. Krotkov NA, McLinden CA, Li C, Lamsal LN, Celarier EA, Marchenko SV, et al. Aura OMI observations of regional SO 2 and NO 2 pollution changes from 2005 to 2015. Atmospheric Chemistry and Physics. 2016;16(7):4605-29.
12. Stjern CW, Samset BH, Boucher O, Iversen T, Lamarque JF, Myhre G, et al. How aerosols and greenhouse gases influence the diurnal temperature range. Atmos Chem Phys. 2020;20(21):13467-80.
13. Fry MM, Naik V, West JJ, Schwarzkopf MD, Fiore AM, Collins WJ, et al. The influence of ozone precursor emissions from four world regions on tropospheric composition and radiative climate forcing. Journal of Geophysical Research: Atmospheres. 2012;117(D7): https://doi.org/10.1029/2011JD017134.
14. Rogelj J, Meinshausen M, Schaeffer M, Knutti R, Riahi K. Impact of short-lived non-CO2 mitigation on carbon budgets for stabilizing global warming. Environmental Research Letters. 2015;10(7):https://doi.org/10.1088/748-9326/10/7/075001.
15. Nam K-M, Waugh CJ, Paltsev S, Reilly JM, Karplus VJ. Carbon co-benefits of tighter SO2 and NOx regulations in China. Global Environmental Change. 2013;23(6):1648-61.
16. Yang J, Zhao Y, Cao J, Nielsen CP. Co-benefits of carbon and pollution control policies on air quality and health till 2030 in China. Environment International. 2021 2021/07/01/;152:https://doi.org/10.1016/j.envint.2021.106482.
17. Rao S, Pachauri S, Dentener F, Kinney P, Klimont Z, Riahi K, et al. Better air for better health: Forging synergies in policies for energy access, climate change and air pollution. Global Environmental Change. 2013;23(5):1122-30.
18. Huang R-J, Zhang Y, Bozzetti C, Ho K-F, Cao J-J, Han Y, et al. High secondary aerosol contribution to particulate pollution during haze events in China. Nature. 2014;514(7521):218-22.
19. Peng W, Yang J, Lu X, Mauzerall DL. Potential co-benefits of electrification for air quality, health, and CO2 mitigation in 2030 China. Applied energy. 2018;218:511-9.
20. Liu F, Zhang Q, Zheng B, Tong D, Yan L, Zheng Y, et al. Recent reduction in NO x emissions over China: synthesis of satellite observations and emission inventories. Environmental Research Letters. 2016;11(11):https://doi.org/10.1088/748-9326/11/11/114002.
21. Itahashi S, Yumimoto K, Kurokawa J-i, Morino Y, Nagashima T, Miyazaki K, et al. Inverse estimation of NO x emissions over China and India 2005–2016: contrasting recent trends and future perspectives. Environmental Research Letters. 2019;14(12):https://doi.org/10.1088/748-9326/ab4d7f.
22. Dammers E, McLinden CA, Griffin D, Shephard MW, Graaf SVD, Lutsch E, et al. NH 3 emissions from large point sources derived from CrIS and IASI satellite observations. Atmospheric chemistry and physics. 2019;19(19):12261-93.
23. Wang Y, Wang J, Xu X, Henze DK, Qu Z, Yang K. Inverse modeling of SO 2 and NO x emissions over China using multisensor satellite data–Part 1: Formulation and sensitivity analysis. Atmospheric Chemistry and Physics. 2020;20(11):6631-50.
24. Rogelj J, Schaeffer M, Meinshausen M, Shindell DT, Hare W, Klimont Z, et al. Disentangling the effects of CO2 and short-lived climate forcer mitigation. Proceedings of the National Academy of Sciences. 2014;111(46):16325-30.
25. Bowerman NH, Frame DJ, Huntingford C, Lowe JA, Smith SM, Allen MR. The role of short-lived climate pollutants in meeting temperature goals. Nature Climate Change. 2013;3(12):1021-4.
26. West JJ, Smith SJ, Silva RA, Naik V, Zhang Y, Adelman Z, et al. Co-benefits of mitigating global greenhouse gas emissions for future air quality and human health. Nature climate change. 2013;3(10):885-9.
27. Hu X, Sun Y, Liu J, Meng J, Wang X, Yang H, et al. The impact of environmental protection tax on sectoral and spatial distribution of air pollution emissions in China. Environmental Research Letters. 2019;14(5):054013.
28. Anenberg SC, Schwartz J, Shindell D, Amann M, Faluvegi G, Klimont Z, et al. Global air quality and health co-benefits of mitigating near-term climate change through methane and black carbon emission controls. Environmental health perspectives. 2012;120(6):831-9.
29. Suarez-Bertoa R, Mendoza-Villafuerte P, Riccobono F, Vojtisek M, Pechout M, Perujo A, et al. On-road measurement of NH3 emissions from gasoline and diesel passenger cars during real world driving conditions. Atmospheric Environment. 2017 2017/10/01/;166:488-97.
30. Fuglestvedt J, Berntsen T, Myhre G, Rypdal K, Skeie RB. Climate forcing from the transport sectors. Proceedings of the National Academy of Sciences. 2008;105(2):454-8.
31. Thambiran T, Diab RD. Air pollution and climate change co-benefit opportunities in the road transportation sector in Durban, South Africa. Atmospheric Environment. 2011;45(16):2683-9.
32. Sharma G, Sinha B, Pallavi, Hakkim H, Chandra BP, Kumar A, et al. Gridded emissions of CO, NO x, SO2, CO2, NH3, HCl, CH4, PM2. 5, PM10, BC, and NMVOC from open municipal waste burning in India. Environmental science & technology. 2019;53(9):4765-74.
33. Wiedinmyer C, Yokelson RJ, Gullett BK. Global emissions of trace gases, particulate matter, and hazardous air pollutants from open burning of domestic waste. Environmental science & technology. 2014;48(16):9523-30.
34. Yang X, Teng F, Wang G. Incorporating environmental co-benefits into climate policies: a regional study of the cement industry in China. Applied energy. 2013;112:1446-53.
35. Liu J, Tong D, Zheng Y, Cheng J, Qin X, Shi Q, et al. Carbon and air pollutant emissions from China's cement industry 1990–2015: trends, evolution of technologies, and drivers. Atmos Chem Phys. 2021;21(3):1627-47.
36. De Gouw JA, Parrish DD, Frost GJ, Trainer M. Reduced emissions of CO2, NOx, and SO2 from US power plants owing to switch from coal to natural gas with combined cycle technology. Earth's Future. 2014;2(2):75-82.
37. Qian H, Xu S, Cao J, Ren F, Wei W, Meng J, et al. Air pollution reduction and climate co-benefits in China’s industries. Nature Sustainability. 2021 2021/05/01;4(5):417-25.
38. Myhre G, Aas W, Cherian R, Collins W, Faluvegi G, Flanner M, et al. Multi-model simulations of aerosol and ozone radiative forcing due to anthropogenic emission changes during the period 1990–2015. Atmospheric Chemistry and Physics. 2017;17(4):2709-20.
39. Crippa M, Guizzardi D, Muntean M, Schaaf E, Dentener F, Van Aardenne JA, et al. Gridded emissions of air pollutants for the period 1970–2012 within EDGAR v4. 3.2. Earth Syst Sci Data. 2018;10(4):1987-2013.
40. Janssens-Maenhout G, Crippa M, Guizzardi D, Dentener F, Muntean M, Pouliot G, et al. HTAP_v2. 2: a mosaic of regional and global emission grid maps for 2008 and 2010 to study hemispheric transport of air pollution. Atmospheric Chemistry and Physics. 2015;15(19):11411-32.
41. Hoesly RM, Smith SJ, Feng L, Klimont Z, Janssens-Maenhout G, Pitkanen T, et al. Historical (1750–2014) anthropogenic emissions of reactive gases and aerosols from the Community Emissions Data System (CEDS). Geoscientific Model Development. 2018;11(1):369-408.
42. Dong H, Dai H, Dong L, Fujita T, Geng Y, Klimont Z, et al. Pursuing air pollutant co-benefits of CO2 mitigation in China: A provincial leveled analysis. Applied Energy. 2015;144:165-74.
43. Zhang Q, Zheng Y, Tong D, Shao M, Wang S, Zhang Y, et al. Drivers of improved PM2. 5 air quality in China from 2013 to 2017. Proceedings of the National Academy of Sciences. 2019;116(49):24463-9.
44. Zhai S, Jacob DJ, Wang X, Shen L, Li K, Zhang Y, et al. Fine particulate matter (PM 2.5) trends in China, 2013–2018: Separating contributions from anthropogenic emissions and meteorology. Atmospheric Chemistry and Physics. 2019;19(16):11031-41.
45. Zheng B, Tong D, Li M, Liu F, Hong C, Geng G, et al. Trends in China's anthropogenic emissions since 2010 as the consequence of clean air actions. Atmospheric Chemistry and Physics. 2018;18(19):14095-111.
46. Zhao Y, Zhang J, Nielsen CP. The effects of energy paths and emission controls and standards on future trends in China's emissions of primary air pollutants. Atmospheric Chemistry and Physics. 2014;14(17):8849-68.
47. Sun W, Shao M, Granier C, Liu Y, Ye C, Zheng J. Long‐term trends of Anthropogenic SO2, NOx, CO, and NMVOCs emissions in China. Earth's Future. 2018;6(8):1112-33.
48. Li M, Liu H, Geng G, Hong C, Liu F, Song Y, et al. Anthropogenic emission inventories in China: a review. National Science Review. 2017;4(6):834-66.
49. Saikawa E, Kim H, Zhong M, Avramov A, Zhao Y, Janssens-Maenhout G, et al. Comparison of emissions inventories of anthropogenic air pollutants and greenhouse gases in China. Atmospheric Chemistry and Physics. 2017;17(10):6393-421.
50. Zheng H, Cai S, Wang S, Zhao B, Chang X, Hao J. Development of a unit-based industrial emission inventory in the Beijing–Tianjin–Hebei region and resulting improvement in air quality modeling. Atmospheric Chemistry and Physics. 2019;19(6):3447-62.
51. Qi J, Zheng B, Li M, Yu F, Chen C, Liu F, et al. A high-resolution air pollutants emission inventory in 2013 for the Beijing-Tianjin-Hebei region, China. Atmospheric Environment. 2017;170:156-68.
52. An J, Huang Y, Huang C, Wang X, Yan R, Wang Q, et al. Emission inventory of air pollutants and chemical speciation for specific anthropogenic sources based on local measurements in the Yangtze River Delta region, China. Atmospheric Chemistry and Physics. 2021;21(3):2003-25.
53. Huang C, Chen C, Li L, Cheng Z, Wang H, Huang H, et al. Emission inventory of anthropogenic air pollutants and VOC species in the Yangtze River Delta region, China. Atmospheric Chemistry and Physics. 2011;11(9):4105-20.
54. Shen G, Tao S, Wei S, Chen Y, Zhang Y, Shen H, et al. Field measurement of emission factors of PM, EC, OC, parent, nitro-, and oxy-polycyclic aromatic hydrocarbons for residential briquette, coal cake, and wood in rural Shanxi, China. Environmental science & technology. 2013;47(6):2998-3005.
55. Bai X, Tian H, Liu X, Wu B, Liu S, Hao Y, et al. Spatial-temporal variation characteristics of air pollution and apportionment of contributions by different sources in Shanxi province of China. Atmospheric Environment. 2021;244:https://doi.org/10.1016/j.atmosenv.2020.117926.
56. Crippa M, Solazzo E, Huang G, Guizzardi D, Koffi E, Muntean M, et al. High resolution temporal profiles in the Emissions Database for Global Atmospheric Research (EDGAR). Nature Scientific Data. 2019:doi:10.1038/s41597-020-0462-2.
57. Tao S, Ru M, Du W, Zhu X, Zhong Q, Li B, et al. Quantifying the rural residential energy transition in China from 1992 to 2012 through a representative national survey. Nature Energy. 2018;3(7):567-73.
58. Kurokawa J, Ohara T. Long-term historical trends in air pollutant emissions in Asia: Regional Emission inventory in ASia (REAS) version 3. Atmospheric Chemistry and Physics. 2020;20(21):12761-93.
59. Zhao Y, Zhang J, Nielsen C. The effects of recent control policies on trends in emissions of anthropogenic atmospheric pollutants and CO 2 in China. Atmospheric Chemistry and Physics. 2013;13(2):487-508.
60. Crippa M, Oreggioni G, Guizzardi D, Muntean M, Schaaf E, Lo Vullo E, et al. Fossil CO2 and GHG emissions of all world countries - 2019 Report. EUR 29849 EN, Publications Office of the European Union. 2019;Luxembourg( ISBN 978-92-76-11100-9):doi:10.2760/687800, JRC117610.
61. Meng W, Zhong Q, Yun X, Zhu X, Huang T, Shen H, et al. Improvement of a global high-resolution ammonia emission inventory for combustion and industrial sources with new data from the residential and transportation sectors. Environmental science & technology. 2017;51(5):2821-9.
62. Wang R, Tao S, Shen H, Huang Y, Chen H, Balkanski Y, et al. Trend in global black carbon emissions from 1960 to 2007. Environmental science & technology. 2014;48(12):6780-7.
63. Zheng Y, Xue T, Zhang Q, Geng G, Tong D, Li X, et al. Air quality improvements and health benefits from China’s clean air action since 2013. Environmental Research Letters. 2017;12(11):https://doi.org/10.1088/748-9326/aa8a32.
64. Xia Y, Zhao Y, Nielsen CP. Benefits of China's efforts in gaseous pollutant control indicated by the bottom-up emissions and satellite observations 2000–2014. Atmospheric Environment. 2016;136:43-53.
65. Lin X, Zhang W, Crippa M, Peng S, Han P, Zeng N, et al. A comparative study of anthropogenic CH4 emissions over China based on the ensembles of bottom-up inventories. Earth Syst Sci Data. 2021;13(3):1073-88.
66. Peng S, Piao S, Bousquet P, Ciais P, Li B, Lin X, et al. Inventory of anthropogenic methane emissions in mainland China from 1980 to 2010. Atmos Chem Phys 2016;16:14545-62.
67. Han P, Zeng N, Oda T, Lin X, Crippa M, Guan D, et al. Evaluating China's fossil-fuel CO 2 emissions from a comprehensive dataset of nine inventories. Atmospheric Chemistry & Physics. 2020;20(19):11371-85.
68. Sheng J, Tunnicliffe R, Ganesan A, Maasakkers J, Shen L, Prinn R, et al. Sustained methane emissions from China after 2012 despite declining coal production and rice-cultivated area. 2020:doi: 10.21203/rs.3.rs-95281/v1.
69. Li M, Zhang Q, Zheng B, Tong D, Lei Y, Liu F, et al. Persistent growth of anthropogenic non-methane volatile organic compound (NMVOC) emissions in China during 1990–2017: drivers, speciation and ozone formation potential. Atmospheric Chemistry and Physics. 2019;19(13):8897-913.
70. Shang Z, Zhou F, Smith P, Saikawa E, Ciais P, Chang J, et al. Weakened growth of cropland‐N2O emissions in China associated with nationwide policy interventions. Global change biology. 2019;25(11):3706-19.
71. Wang Y, Zhang Q, He K, Zhang Q, Chai L. Sulfate-nitrate-ammonium aerosols over China: response to 2000–2015 emission changes of sulfur dioxide, nitrogen oxides, and ammonia. Atmospheric Chemistry and Physics. 2013;13(5):2635-52.
72. van der A RJ, Mijling B, Ding J, Koukouli ME, Liu F, Li Q, et al. Cleaning up the air: effectiveness of air quality policy for SO 2 and NO x emissions in China. Atmospheric Chemistry and Physics. 2017;17(3):1775-89.
73. Tang L, Qu J, Mi Z, Bo X, Chang X, Anadon LD, et al. Substantial emission reductions from Chinese power plants after the introduction of ultra-low emissions standards. Nature Energy. 2019;4(11):929-38.
74. Peng L, Zhang Q, Yao Z, Mauzerall DL, Kang S, Du Z, et al. Underreported coal in statistics: A survey-based solid fuel consumption and emission inventory for the rural residential sector in China. Applied Energy. 2019;235:1169-82.
75. Zhao Y, Nielsen CP, Lei Y, McElroy MB, Hao J. Quantifying the uncertainties of a bottom-up emission inventory of anthropogenic atmospheric pollutants in China. Atmospheric Chemistry and Physics. 2011;11(5):2295-308.
76. Zhao Y, Nielsen CP, McElroy MB, Zhang L, Zhang J. CO emissions in China: uncertainties and implications of improved energy efficiency and emission control. Atmospheric Environment. 2012;49:103-13.
77. Lei Y, Zhang Q, Nielsen C, He K. An inventory of primary air pollutants and CO2 emissions from cement production in China, 1990–2020. Atmospheric Environment. 2011;45(1):147-54.
78. Liu J, Tong D, Zheng Y, Cheng J, Qin X, Shi Q, et al. Carbon and air pollutant emissions from China's cement industry 1990–2015: trends, evolution of technologies and drivers. Atmospheric Chemistry and Physics 2021;21:1627-47.
79. Tian H, Gao J, Hao J, Lu L, Zhu C, Qiu P. Atmospheric pollution problems and control proposals associated with solid waste management in China: a review. Journal of Hazardous Materials. 2013;252:142-54.
80. CSY. China Statistical Yearbook. 2020:National Bureau of Statistics of China.