50 citations as recorded by crossref.

1. First simultaneous measurements of peroxyacetyl nitrate (PAN) and ozone at Nam Co in the central Tibetan Plateau: impacts from the PBL evolution and transport processes X. Xu et al.
2. Characterizations and Potential Formation Pathways of Atmospheric Inorganic Ions at a National Background Site in the Northeastern Qinghai‐Tibet Plateau During Autumn Season B. Han et al.
3. Regional sources of NH3, SO2 and CO in the Third Pole B. Sharma et al.
4. Religious burning as a potential major source of atmospheric fine aerosols in summertime Lhasa on the Tibetan Plateau Y. Cui et al.
5. Changes in glacier albedo and the driving factors in the Western Nyainqentanglha Mountains from 2001 to 2020 S. Ren et al.
6. Chemical characterization and sources of submicron aerosols in Lhasa on the Qinghai–Tibet Plateau: Insights from high-resolution mass spectrometry W. Zhao et al.
7. Comprehensive measurement of carbonyls in Lhasa, Tibetan Plateau: Implications for strong atmospheric oxidation capacity X. Guo et al.
8. Observations of atmospheric pollutants at Lhasa during 2014–2015: Pollution status and the influence of meteorological factors B. Duo et al.
9. Tropospheric ozone as an atmospheric pollutant and short-lived climate forcer in the Third Pole B. Sharma et al.
10. Chemical composition of size-segregated aerosols in Lhasa city, Tibetan Plateau X. Wan et al.
11. Gaseous and particulate pollutants in Lhasa, Tibet during 2013–2017: Spatial variability, temporal variations and implications X. Yin et al.
12. Urban ozone sink inferred from surface measurements in China X. Zhang et al.
13. Deep stratospheric intrusion and Russian wildfire induce enhanced tropospheric ozone pollution over the northern Tibetan Plateau J. Zhang et al.
14. Retrieval of Tropospheric NO2 Vertical Column Densities from Ground-Based MAX-DOAS Measurements in Lhasa, a City on the Tibetan Plateau S. Cheng et al.
15. Mobile MAX-DOAS observations of tropospheric NO2 and HCHO during summer over the Three Rivers' Source region in China S. Cheng et al.
16. Effects of the opening of the Qinghai–Tibet Railway on municipal solid waste management generation in Lhasa X. Ding & J. Wang
17. Size-Segregated Characteristics of Carbonaceous Aerosols during the Monsoon and Non-Monsoon Seasons in Lhasa in the Tibetan Plateau N. Wei et al.
18. Diurnal variations in the spatial patterns of air pollution across Delhi P. O’Shea et al.
19. The reduction in C2H6 from 2015 to 2020 over Hefei, eastern China, points to air quality improvement in China Y. Sun et al.
20. 臭氧卫星遥感反演进展及挑战 迟. Chi Yulei & 赵. Zhao Chuanfeng
21. Surface ozone pollution in China: Trends, exposure risks, and drivers C. He et al.
22. Characteristics of size distributions and sources of water-soluble ions in Lhasa during monsoon and non-monsoon seasons N. Wei et al.
23. Measurement report: Vertical profiling of particle size distributions over Lhasa, Tibet – tethered balloon-based in situ measurements and source apportionment L. Ran et al.
24. Characteristics of Cloud and Aerosol Derived from Lidar Observations during Winter in Lhasa, Tibetan Plateau X. Jin et al.
25. Long-term variability of trace gases over the Indian Western Himalayan Region R. Masiwal et al.
26. Quantifying variability, source, and transport of CO in the urban areas over the Himalayas and Tibetan Plateau Y. Sun et al.
27. Spatiotemporal variations of surface ozone and its influencing factors across Tibet: A Geodetector-based study Y. Chen et al.
28. Impacts of deep boundary layer on near-surface ozone concentration over the Tibetan Plateau Y. Chou et al.
29. Ambient Gaseous Pollutants in an Urban Area in South Africa: Levels and Potential Human Health Risk O. Morakinyo et al.
30. Surface ozone over the Tibetan Plateau controlled by stratospheric intrusion X. Yin et al.
31. Measurement report: Source apportionment and environmental impacts of volatile organic compounds (VOCs) in Lhasa, a highland city in China C. Ye et al.
32. Assessment of particulate matter concentration and gaseous pollutants in urban and rural regions over the Emirate of Abu Dhabi, UAE D. Phanikumar et al.
33. Spatial and seasonal characteristics of particulate matter and gaseous pollution in China: Implications for control policy X. Ma et al.
34. Melting of the Chhota Shigri Glacier, Western Himalaya, Insensitive to Anthropogenic Emission Residues: Insights From Geochemical Evidence S. Nizam et al.
35. Study on the dynamic characteristics of groundwater in the valley plain of Lhasa City J. Liu et al.
36. High-resolution ground-level O3 estimation in China (2019–2024) via self-attention networks: Unveiling spatiotemporal dynamics and key drivers P. Wang et al.
37. Spatial and temporal variation of particulate matter and gaseous pollutants in China during 2014–2016 R. Li et al.
38. Four-year assessment of ambient particulate matter and trace gases in the Delhi-NCR region of India S. Hama et al.
39. Ozone production sensitivity in the highland city of Lhasa: a comparative analysis with Beijing Y. Chen et al.
40. Long-term trends in the total columns of ozone and its precursor gases derived from satellite measurements during 2004–2015 over three different regions in South Asia: Indo-Gangetic Plain, Himalayas and Tibetan Plateau D. Rupakheti et al.
41. Trends in air pollutants emissions in the Qinghai-Tibet Plateau and its surrounding areas under different socioeconomic scenarios K. Jiang et al.
42. The Contribution of Local Anthropogenic Emissions to Air Pollutants in Lhasa on the Tibetan Plateau S. Chen et al.
43. Variations of air pollutant response to COVID-19 lockdown in cities of the Tibetan Plateau X. Chen et al.
44. Spatio-temporal patterns of air pollution in China from 2015 to 2018 and implications for health risks M. Kuerban et al.
45. Volatile organic compounds in urban Lhasa: variations, sources, and potential risks S. Guo et al.
46. Rapid increases in ozone concentrations over the Tibetan Plateau caused by local and non-local factors C. Xu et al.
47. Surface ozone in southeast Tibet: variations and implications of tropospheric ozone sink over a highland Y. Chen et al.
48. Rapid increase in atmospheric glyoxal and methylglyoxal concentrations in Lhasa, Tibetan Plateau: Potential sources and implications Q. Li et al.
49. Surface ozone at Nam Co in the inland Tibetan Plateau: variation, synthesis comparison and regional representativeness X. Yin et al.
50. Atmospheric Contamination of Coastal Cities by the Exhaust Emissions of Docked Marine Vessels: The Case of Tromsø A. Zubiaga et al.