# | Document title | Authors | Year | Source | Cited by |
1 | Characteristics of nanoparticles emitted from burning of biomass fuels | Hata M., Chomanee J., Thongyen T., Bao L., Tekasakul S., Tekasakul P., Otani Y., Furuuchi M. | 2014 | Journal of Environmental Sciences (China) 26(9),pp. 1913-1920 | 40 |
2 | Impact of transport of fine and ultrafine particles from open biomass burning on air quality during 2019 Bangkok haze episode | Dejchanchaiwong R., Tekasakul P., Tekasakul S., Phairuang W., Nim N., Sresawasd C., Thongboon K., Thongyen T., Suwattiga P. | 2020 | Journal of Environmental Sciences (China) 97,pp. 149-161 | 26 |
3 | Development of PM0.1 personal sampler for evaluation of personal exposure to aerosol nanoparticles | Thongyen T., Hata M., Toriba A., Ikeda T., Koyama H., Otani Y., Furuuchi M. | 2015 | Aerosol and Air Quality Research 15(1),pp. 180-187 | 12 |
4 | Deliberation between PM1 and PM2.5 as air quality indicators based on comprehensive characterization of urban aerosols in Bangkok, Thailand | Vejpongsa I., Suvachittanont S., Klinklan N., Thongyen T., Veres M., Szymanski W., Szymanski W. | 2017 | Particuology 35,pp. 1-9 | 10 |
5 | Vertical variation of carbonaceous aerosols within the PM2.5 fraction in Bangkok, Thailand | Choomanee P., Bualert S., Thongyen T., Salao S., Szymanski W.W., Szymanski W.W., Rungratanaubon T. | 2020 | Aerosol and Air Quality Research 20(1),pp. 43-52 | 9 |
6 | Development of a high-volume air sampler for nanoparticles | Hata M., Thongyen T., Bao L., Hoshino A., Otani Y., Ikeda T., Furuuchi M. | 2013 | Environmental Sciences: Processes and Impacts 15(2),pp. 454-462 | 9 |
7 | Ozone formation potential of ambient volatile organic compounds at roadside in Bangkok, Thailand | Fakkaew N., Bualert S., Thongyen T., Rungratanaubon T. | 2021 | Applied Environmental Research 43(4),pp. 14-28 | 2 |
8 | Experimental assessment of tropical surface ozone related to land utilization in Central Thailand | Choomanee P., Bualert S., Thongyen T., Duangmal K., Intaraksa A., Rungratanaubon T., Szymanski W.W., Szymanski W.W. | 2021 | Atmospheric Environment: X 11 | 1 |
9 | Worker’s personal exposure to pm0.1 and pm4 titanium dioxide nanomaterials during packaging | Higashikubo I., Handika R.A., Handika R.A., Kawamoto T., Shimizu H., Thongyen T., Piriyakarnsakul S., Piriyakarnsakul S., Muhammad A., Hata M., Furuuchi M., Furuuchi M. | 2021 | Aerosol and Air Quality Research 21(6) | 1 |
10 | Secondary sources of PM2.5 based on the vertical distribution of organic carbon, elemental carbon, and water-soluble ions in Bangkok | Rattanapotanan T., Thongyen T., Bualert S., Choomanee P., Suwattiga P., Rungrattanaubon T., Utavong T., Phupijit J., Changplaiy N. | 2023 | Environmental Advances 11 | 1 |
11 | Transboundary haze from peatland fires and local source-derived PM2.5 in Southern Thailand | Promsiri P., Tekasakul S., Thongyen T., Suwattiga P., Morris J., Latif M.T., Tekasakul P., Dejchanchaiwong R. | 2023 | Atmospheric Environment 294 | 0 |