[1]
|
Y. Zhu, J. Xie, F. Huang and L. Cao, “Association between short-term exposure to air pollution and COVID-19 infection: Evidence from China,” Science of The Total Environment, 727, 2020.
|
[2]
|
M. Bauwens, S. Compernolle, T. Stavrakou, J.-F. Müller, J. Van Gent, H. Eskes, P. F. Levelt, R. Van Der A, J. P. Veefkind, J. Vlietinck and C. Zehner, “Impact of Coronavirus outbreak on NO2 pollution assessed using TROPOMI and OMI observations,” Geophysical Research Letters, 47, 2020.
|
[3]
|
P. M. Forster, H. I. Forster, M. J. Evans, M. J. Gidden, C. D. Jones, C. A. Keller, R. D. Lamboll, C. Le Quéré, J. Rogelj, D. Rosen, C.-F. Schleussner, T. B. Richardson and C. Smith, “Current and future global climate impacts resulting from COVID-19,” Nature Climate Change, 10, 2020.
|
[4]
|
P. Samani, C. García-Velásquez, P. Fleury and Y. v. der Meer, "The Impact of the COVID-19 outbreak on climate change and air quality: four country case studies," Global Sustainability, 4, 2021.
|
[5]
|
N. Evangeliou, S. M. Platt, S. Eckhardt, C. L. Myhre, P. Laj, L. Alados-Arboledas, J. Backman, B. T. Brem, M. Fiebig, H. Flentje, A. Marinoni, M. Pandolfi, J. Yus-Dìez, N. Prats and P, “Changes in black carbon emissions over Europe due to COVID-19 lockdowns,” Atmospheric Chemistry and Physics, 21, 2021.
|
[6]
|
C. Le Quéré, R. B. Jackson, M. W. Jones, A. J. P. Smith , S. Abernethy, R. M. Andrew, A. J. De-Gol , D. R. Willis, Y. Shan, J. G. Canadell, P. Friedlingstein, F. Creutzig and G. P. Peters, “Temporary reduction in daily global CO2 emissions during the COVID-19 forced confinement,” Nature Climate Change, 10, 2020.
|
[7]
|
A. J. Turner, J. Kim, H. Fitzmaurice, C. Newman, K. Worthington, K. Chan, P. J. Wooldridge, P. Köehler, C. Frankenberg and R. C. Cohen, “Observed impacts of COVID-19 on urban CO2 emissions,” Geophysical Research Letters, 47, 2020.
|
[8]
|
C. D. Jones, J. E. Hickman, S. T. Rumbold, J. Walton, R. D. Lamboll, R. B. Skeie, S. Fiedler, P. M. Forster, J. Rogelj, M. Abe, M. Botzet, K. Calvin, C. Cassou and J. N. Cole, “The Climate Response to Emissions Reductions Due to COVID-19: Initial Results From CovidMIP,” Geophysical Research Letters, 48, 2021.
|
[9]
|
H. Sugawara, S. Ishidoya, Y. Terao, Y. Takane, Y. Kikegawa and K. Nakajima, "Anthropogenic CO2 Emissions Changes in an Urban Area of Tokyo, Japan, Due to the COVID-19 Pandemic: A Case Study During the State of Emergency in April–May 2020," Geophysical Research Letters, 48, 2021.
|
[10]
|
C. Bertram, G. Luderer, F. Creutzig, N. Bauer, F. Ueckerdt, A. Malik and O. Edenhofer, “COVID-19-induced low power demand and market forces starkly reduce CO2 emissions,” Nature Climate Change, 11, 2021.
|
[11]
|
B. R. Parida, S. Bar, D. Kaskaoutis, A. C. Pandey, S. D. Polade and S. Goswami, “Impact of COVID-19 induced lockdown on land surface temperature, aerosol, and urban heat in Europe and North America,” Sustainable Cities and Society, 75, 2021.
|
[12]
|
T. R. Oke, G. Mills, A. Christen and J. A. Voogt, Urban Climates, Cambridge University Press, 2017.
|
[13]
|
F. Fujibe, “Temperature anomaly in the Tokyo Metropolitan Area during the COVID-19 (coronavirus) self-restraint period,” Scientific Online Letters on the Atmosphere, 16, 2020.
|
[14]
|
K. Nakajima, Y. Takane, Y. Kikegawa, Y. Furuta and H. Takamatsu, "Human behaviour change and its impact on urban climate: Restrictions with the G20 Osaka Summit and COVID-19 outbreak," Urban Climate, 35, 2021.
|
[15]
|
Z. Liu, J. Lai, W. Zhan, B. Bechtel, J. Voogt, J. Quan, L. Hu, P. Fu, F. Huang, L. Li, Z. Guo and J. Li, “Urban heat islands significantly reduced by COVID-19 lockdown,” Geophysical Research Letters, 49, 2022.
|
[16]
|
F. Kimura and S. Takahashi, “The effects of land-use and anthropogenic heating on the surface temperature in the Tokyo Metropolitan area: A numerical experiment,” Atmospheric Environment, 25, 1991.
|
[17]
|
T. Ichinose, K. Shimodozono and K. Hanaki, “Impact of anthropogenic heat on urban climate in Tokyo,” Atmospheric Environment, 33, 1999.
|
[18]
|
Y. Ohashi, Y. Genchi, H. Kondo, Y. Kikegawa, H. Yoshikado and Y. Hirano, “Influence of air-conditioning waaste heat on air temperature in Tokyo during summer: numerical experiments using an urban canopy model coupled with a building energy model,” Journal of Applied Meteorology and Climatology, 46, 2007.
|
[19]
|
C. De Munck, G. Pigeon, V. Masson, F. Meunier, P. Bousquet, B. Tréméac, M. Merchat, P. Poeuf and C. Marchadier, “How much can air conditioning increase air temperatures for a city like Paris, France?,” International Journal of Climatology, 33, 2013.
|
[20]
|
F. Salamanca, M. Georgescu, A. Mahalov, M. Moustaoui and M. Wang, “Anthropogenic heating of the urban environment due to air conditioning,” Journal of Geophysical Research Atmosphere, 119, 2014.
|
[21]
|
Y. Takane, Y. Kikegawa, M. Hara, T. Ihara, Y. Ohashi, S. A. Adachi, H. Kondo, K. Yamaguchi and N. Kaneyasu, “A climatological validation of urban air temperature and electricity demand simulated by a regional climate model coupled with an urban canopy model and a building energy model in an Asian megacity,” International Journal of Climatology, 37, 2017.
|
[22]
|
Y. Wang, Y. Li, S. D. Sabatino, A. Martilli and P. W. Chan, “Effects of anthropogenic heat due to air-conditioning systems on an extreme high temperature event in Hong Kong,” Environmental Research Letters, 13, 2018.
|
[23]
|
X. Xu, F. Chen, S. Shen, S. Miao, M. Barlage, W. Guo and A. Mahalov, “Using WRF-Urban to assess summertime air conditioning electric loads and their impacts on urban weather in Beijing,” Journal of Geophysical Research Atmosphere, 123, 2018.
|
[24]
|
Y. Takane, Y. Kikegawa, M. Hara and C. S. B. Grimmond, “Urban warming and future air-conditioning use in an Asian megacity: importance of positive feedback,” npj Climate and Atmospheric Science, 2, 2019.
|
[25]
|
IPCC, “AR6 Climate Change 2021: The Physical Science Basis,” 2021.
|
[26]
|
H. Kusaka, H. Kondo, Y. Kikegawa and F. Kimura, "A simple single-layer urban canopy model for atmospheric models: Comparison with multi-layer and slab models," Boundary-Layer Meteorology, 101, 2001.
|
[27]
|
Y. Kikegawa, Y. Genchi, H. Yoshikado and H. Kondo, "Development of a numerical simulation system toward comprehensive assessments of urban warming countermeasures including their impacts upon the urban buildings' energy-demands," Applied Energy, 76, 2003.
|
[28]
|
F. Salamanca, A. Krpo, A. Martilli and A. Clappier, “A new building energy model coupled with an urban canopy parameterization for urban climate simulations—part I. formulation, verification, and sensitivity analysis of the model,” Theoretical and Applied Climatology, 99, 2010.
|
[29]
|
F. Salamanca and A. Martilli , “A new Building Energy Model coupled with an Urban Canopy Parameterization for urban climate simulations—part II. Validation with one dimension off-line simulations,” Theoretical and Applied Climatology, 99, 2010.
|
[30]
|
D. o. E. a. S. A. United Nations, “World Urbanization Prospects: The 2014 Revision,” (ST/ESA/SER.A/366), 2015.
|
[31]
|
K. Oleson, “Contrasts between Urban and Rural Climate in CCSM4 CMIP5 Climate Change Scenarios,” Journal of Climate, 25, 2012.
|
[32]
|
H. Kusaka, M. Hara and Y. Takane, “Urban climate projection by the WRF model at 3–km grid increment: dynamical downscaling and predicting heat stress in the 2070’s August for Tokyo, Osaka, and Nagoya,” Journal of Meteorological Society of Japan, 90B, 2012.
|
[33]
|
M. Georgescu, M. Moustaoui , A. Mahalov and J. Dudhia , “Summer-time climate impacts of projected megapolitan expansion in Arizona,” Nature Climate Change, 3, 2013.
|
[34]
|
A. C. G. Varquez and M. Kanda, “Global urban climatology: a meta-analysis of air temperature trends (1960-2009),” NPJ Climate and Atmospheric Science, 1, 2018.
|
[35]
|
E. S. Krayenhoff, M. Moustaoui, A. M. Broadbent , V. Gupta and M. Georgescu, “Diurnal interaction between urban expansion, climate change and adaptation in US cities,” Nature Climate Change, 8, 2018.
|
[36]
|
Y. Takane, Y. Ohashi, C. S. B. Grimmond, M. Hara and Y. Kikegawa, “Asian megacity heat stress under future climate scenarios: Impact of air-conditioning feedback,” Environmental Research Communications, 2, 2021.
|
[37]
|
M. Georgescu, P. E. Morefield, B. G. Bierwagen and C. P. Weaver, “Urban adaptation can roll back warming of emerging megapolitan regions,” Proceedings of the National Academy of Sciences of the United States of America, 111, 2014.
|
[38]
|
N. H. Wong, C. L. Tan, D. D. Kolokotsa and H. Takebayashi , “Greenery as a mitigation and adaptation strategy to urban heat,” Nature Reviews Earth & Environment, 2, 2021.
|
[39]
|
F. Fujibe, “Weekday-weekend differences of urban climates Part 1: temporal variation of air temperature,” Journal of the Meteorological Society of Japan. Ser. II, 65, 1987.
|
[40]
|
F. Fujibe, “Day-of-the-week variations of urban temperature and their long-term trends in Japan,” Theoretical and Applied Climatology, 104, 2010.
|
[41]
|
Y. Ohashi, M. Suido, Y. Kikegawa, T. Ihara, Y. Shigeta and M. Nabeshima, “Impact of seasonal variations in weekday electricity use on urban air temperature observed in Osaka, Japan,” Quarterly Journal of the Royal Meteorological Society, 142, 2016.
|
[42]
|
J. Dou and S. Miao, “Impact of mass human migration during Chinese New Year on Beijing urban heat island,” International Journal of Climatology, 37, 2017.
|
[43]
|
K. Nakajima, Y. Takane, K. Yukihiro and Y. Kazuki, “Development of a building energy model to improve the reproducibility of electricity consumption in an urban area,” Journal of advances in Modeling Earth Systems, In preparation, 2022.
|
[44]
|
S. A. Adachi, F. Kimura, H. Kusaka, M. G. Duda, Y. Yamagata, H. Seya, K. Nakamichi and T. Aoyagi, “Moderation of summertime heat island phenomena via modification of the urban form in the Tokyo Metropolitan Area,” Journal of Applied Meteorology and Climatology, 53, 2014.
|
[45]
|
H. Kusaka, A. Suzuki-Parker, T. Aoyagi, S. A. Adachi and Y. Yamagata, “Assessment of RCM and urban scenarios uncertainties in the climate projections for August in the 2050s in Tokyo,” Climatic Change, 137, 2016.
|
[46]
|
D. Bäumer and B. Vogel, “An unexpected pattern of distinct weekly periodicities in climatological variables in Germany,” Geophysical Research Letters, 34, 2007.
|
[47]
|
N. Earl, I. Simmonds and N. Tappe, “Weekly cycles in peak time temperatures and urban heat island intensity,” Environmental Research Letters, 11, 2016.
|
[48]
|
Y. Kikegawa, K. Nakajima, Y. Takane, Y. Ohashi and T. Ihara, “A quantification of classic but unquantified positive feedback effects in the urban-building-energy-climate system,” Applied Energy, 307, 2022.
|
[49]
|
L.-Y. Wu, J.-Y. Zhang and C.-X. Shi, “Mass human migration and the urban heat iisland during the Chinese new year holiday: A case study in Harbin city, Northeast China,” Atmospheric and Oceanic Science Letters, 8, 2015.
|
[50]
|
J. Zhang, L. Wu, F. Yuan, J. Dou and S. Miao, “Mass human migration and Beijing’s urban heat island during the Chinese New Year holiday,” Science Bulletin, 60, 2015.
|
[51]
|
J. Zhang and L. Wu, “Influence of human population movements on urban climate of Beijing during the Chinese New Year holiday,” Scientific Reports, 7, 2017.
|
[52]
|
M. Tewari, F. Salamanca, A. Martilli, L. Treinish and A. Mahalov, “Impacts of projected urban expansion and global warming on cooling energy demand over a semiarid region,” Atmospheric Science Letters, 18, 2017.
|
[53]
|
D. E. Bowler, L. Buyung-Ali , T. M. Knight and A. S. Pullin , “Urban greening to cool towns and cities: A systematic review of the empirical evidence,” Landscape and Urban Planning, 97, 2010.
|
[54]
|
M. Terada, T. Nagata and M. Kobayashi, ““Mobile spatial statistics” supporting development of society and industry — population estimation technology using Mobile network statistical data and applications,” NTT Docomo Technical Journal, 14, 2013.
|
[55]
|
Y. Ohashi, Y. Takane and K. Nakajima, “Impact of COVID-19 pandemic on changes in temperature-sensitive cardiovascular and respiratory disease mortality in Japan,” Nature Human Behaviour, Submitted, 2022.
|
[56]
|
N. Matsubara, “Grasping dynamic population by “Mobile Spatial Statistics”: From the viewpoint of tourism disaster and stranded persons,” Journal of Information Processing and Management, 60, 2017.
|
[57]
|
W. C. Skamarock, J. B. Klemp, J. Dudhia, D. O. Gill, D. M. Barker, W. Wang and J. G. Powers, “A description of the advanced research WRF version 3,” NCAR TECHNICAL NOTE, NCAR/TN–468+STR, 2008.
|
[58]
|
Y. Kikegawa, A. Tanaka, Y. Ohashi, T. Ihara and Y. Shigeta, “Observed and simulated sensitivities of summertime urban surface air temperatures to anthropogenic heat in downtown areas of two Japanese Major Cities, Tokyo and Osaka,” Theoretical and Applied Climatology, 117, 2014.
|
[59]
|
E. Kalnay, M. Kanamitsu, R. Kistler, W. Collins, D. Deaven, L. Gandin, M. Iredell, S. Saha, G. White, J. Woollen, Y. Zhu, A. Leetmaa, R. Reynolds, M. Chelliah, W. Ebisuzaki, W. Higgins, J. Janowiak, K. C. Mo, C. Ropelewski, J. Wang and J, “The NCEP/NCAR 40-year reanalysis project,” Bulletin of the American Meteorological Society, 77, 1996.
|
[60]
|
E. J. Mlawer, S. J. Taubman, P. D. Brown, M. J. Iacono and S. A. Clough, “Radiative transfer for inhomogeneous atmospheres: RRTM, a validated correlated-k model for the longwave,” Journal of Geophysical Research Atmosphere, 102, 1997.
|
[61]
|
M.-D. Chou and M. J. Suarez, “An efficient thermal infrared radiation parameterization for use in general circulation models,” NASA Technical Memorandum, 104606, 1994.
|
[62]
|
T. Matsui, S. Q. Zhang , S. E. Lang, W.-K. Tao, C. Ichoku and C. D. Peters-Lidard , “Impact of radiation frequency, precipitation radiative forcing, and radiation column aggregation on convection-permitting West African monsoon simulations,” Climate Dynamics, 55, 2020.
|
[63]
|
G. Thompson, P. R. Field, R. M. Rasmussen and W. D. Hall, “Explicit forecasts of winter precipitation using an improved bulk microphysics scheme. Part II: Implementation of a new snow parameterization,” Monthly Weather Review, 136, 2008.
|
[64]
|
G. L. Mellor and T. Yamada, “Development of a turbulence closure model for geophysical fluid problems,” Reviews of Geophysics, 20, 1982.
|
[65]
|
Z. I. Janjić, “The step-mountain eta coordinate model: further developments of the convection, viscous sublayer, and turbulence closure schemes,” Monthly Weather Review, 122, 1994.
|
[66]
|
Z. I. Janjić, “Nonsingular implementation of the Mellor-Yamada level 2.5 scheme in the NCEP Meso model,” NCEP Office Note, 437, 2002.
|
[67]
|
F. Chen and J. Dudhia, “Coupling an advanced land surface–hydrology model with the Penn State–NCAR MM5 modeling system. Part I: model implementation and sensitivity,” Monthly Weather Review, 129, 2001.
|
[68]
|
H. Kusaka and F. Kimura, “Thermal effects of urban canyon structure on the nocturnal heat island: Numerical experiment using a mesoscale model coupled with an urban canopy model,” Journal of Applied Meteorology and Climatology, 43, 2004.
|
[69]
|
F. Chen, H. Kusaka, R. Bornstein, J. Ching, C. S. B. Grimmond, S. Grossman-Clarke, T. Loridan, K. W. Manning, A. Martilli, S. Miao, D. Sailor, F. P. Salamanca, H. Taha, M. Tewari and Wang, “The integrated WRF/urban modelling system: development, evaluation, and applications to urban environmental problems,” International Journal of Climatology, 31, 2011.
|
[70]
|
T. Ihara, Y. Kikegawa, K. Asahi, Y. Genchi and H. Kondo, “Changes in year-round air temperature and annual energy consumption in office building areas by urban heat-island countermeasures and energy-saving measures,” Applied Energy, 85, 2008.
|
[71]
|
Y. Kikegawa, Y. Yamakawa, E. Tokutake, Y. Ohashi, Y. Takane, T. Ihara and M. Nabeshima, “Validation of a numerical urban weather forecasting model coupled with a building energy model in terms of the reproducibility of solar irradiance and electricity demand,” Journal of Japan Society of Civil Engineers Ser. G Environmental Research, 73, 2017.
|
[72]
|
Y. Takane, S. Aoki, Y. Kikegawa, Y. Yamakawa, M. Hara, H. Kondo and S. Iizuka, “Future projection of electricity demand and thermal comfort for August in Nagoya city by WRF-CM-BEM,” Journal of Environmental Engineering, AIJ, 80, 2015.
|
[73]
|
K. Nakajima, Y. Takane, S. Fukuba, K. Yamaguchi and Y. Kikegawa, “Urban electricity–temperature relationships in the Tokyo Metropolitan Area,” Energy and Buildings, 256, 2022.
|
[74]
|
T. a. T. Japanese Ministry of Land, Infrastructure, , “Nation-wide road traffic condition study (road traffic census), Fiscal 1999,” 2001.
|
[75]
|
Environment Agency of Japan, “The survey result on automobile exhaust unit rate and total amounts,” 1998.
|
[76]
|
W. Gemmill, B. Katz and X. Li, “Daily real-time, global sea surface temperature - high-resolution analysis at NOAA/NCEP,” NOAA/NWS/NCEP/MMAB Office Note, 260, 2007.
|