Evaluation of 30 urban land surface models in the Urban-PLUMBER project: Phase 1 results

Mathew J. Lipson; Sue Grimmond; Martin Best; Gab Abramowitz; Andrew Coutts; Nigel Tapper; Jong Jin Baik; Meiring Beyers; Lewis Blunn; Souhail Boussetta; Elie Bou-Zeid; Martin G. De Kauwe; Cécile de Munck; Matthias Demuzere; Simone Fatichi; Krzysztof Fortuniak; Beom Soon Han; Margaret A. Hendry; Yukihiro Kikegawa; Hiroaki Kondo; Doo Il Lee; Sang Hyun Lee; Aude Lemonsu; Tiago Machado; Gabriele Manoli; Alberto Martilli; Valéry Masson; Joe McNorton; Naika Meili; David Meyer; Kerry A. Nice; Keith W. Oleson; Seung Bu Park; Michael Roth; Robert Schoetter; Andrés Simón-Moral; Gert Jan Steeneveld; Ting Sun; Yuya Takane; Marcus Thatcher; Aristofanis Tsiringakis; Mikhail Varentsov; Chenghao Wang; Zhi Hua Wang; Andy J. Pitman

doi:10.1002/qj.4589

Evaluation of 30 urban land surface models in the Urban-PLUMBER project: Phase 1 results

Mathew J. Lipson, Sue Grimmond, Martin Best, Gab Abramowitz, Andrew Coutts, Nigel Tapper, Jong Jin Baik, Meiring Beyers, Lewis Blunn, Souhail Boussetta, Elie Bou-Zeid, Martin G. De Kauwe, Cécile de Munck, Matthias Demuzere, Simone Fatichi, Krzysztof Fortuniak, Beom Soon Han, Margaret A. Hendry, Yukihiro Kikegawa, Hiroaki KondoDoo Il Lee, Sang Hyun Lee, Aude Lemonsu, Tiago Machado, Gabriele Manoli, Alberto Martilli, Valéry Masson, Joe McNorton, Naika Meili, David Meyer, Kerry A. Nice, Keith W. Oleson, Seung Bu Park, Michael Roth, Robert Schoetter, Andrés Simón-Moral, Gert Jan Steeneveld, Ting Sun, Yuya Takane, Marcus Thatcher, Aristofanis Tsiringakis, Mikhail Varentsov, Chenghao Wang, Zhi Hua Wang, Andy J. Pitman

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Accurately predicting weather and climate in cities is critical for safeguarding human health and strengthening urban resilience. Multimodel evaluations can lead to model improvements; however, there have been no major intercomparisons of urban-focussed land surface models in over a decade. Here, in Phase 1 of the Urban-PLUMBER project, we evaluate the ability of 30 land surface models to simulate surface energy fluxes critical to atmospheric meteorological and air quality simulations. We establish minimum and upper performance expectations for participating models using simple information-limited models as benchmarks. Compared with the last major model intercomparison at the same site, we find broad improvement in the current cohort's predictions of short-wave radiation, sensible and latent heat fluxes, but little or no improvement in long-wave radiation and momentum fluxes. Models with a simple urban representation (e.g., ‘slab’ schemes) generally perform well, particularly when combined with sophisticated hydrological/vegetation models. Some mid-complexity models (e.g., ‘canyon’ schemes) also perform well, indicating efforts to integrate vegetation and hydrology processes have paid dividends. The most complex models that resolve three-dimensional interactions between buildings in general did not perform as well as other categories. However, these models also tended to have the simplest representations of hydrology and vegetation. Models without any urban representation (i.e., vegetation-only land surface models) performed poorly for latent heat fluxes, and reasonably for other energy fluxes at this suburban site. Our analysis identified widespread human errors in initial submissions that substantially affected model performances. Although significant efforts are applied to correct these errors, we conclude that human factors are likely to influence results in this (or any) model intercomparison, particularly where participating scientists have varying experience and first languages. These initial results are for one suburban site, and future phases of Urban-PLUMBER will evaluate models across 20 sites in different urban and regional climate zones.

Original language	English (US)
Pages (from-to)	126-169
Number of pages	44
Journal	Quarterly Journal of the Royal Meteorological Society
Volume	150
Issue number	758
DOIs	https://doi.org/10.1002/qj.4589
State	Published - Jan 1 2024
Externally published	Yes

Keywords

benchmark
energy balance
intercomparison
model evaluation
urban climate
urban meteorology

ASJC Scopus subject areas

Atmospheric Science

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10.1002/qj.4589

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Lipson, M. J., Grimmond, S., Best, M., Abramowitz, G., Coutts, A., Tapper, N., Baik, J. J., Beyers, M., Blunn, L., Boussetta, S., Bou-Zeid, E., De Kauwe, M. G., de Munck, C., Demuzere, M., Fatichi, S., Fortuniak, K., Han, B. S., Hendry, M. A., Kikegawa, Y., ... Pitman, A. J. (2024). Evaluation of 30 urban land surface models in the Urban-PLUMBER project: Phase 1 results. Quarterly Journal of the Royal Meteorological Society, 150(758), 126-169. https://doi.org/10.1002/qj.4589

Lipson, MJ, Grimmond, S, Best, M, Abramowitz, G, Coutts, A, Tapper, N, Baik, JJ, Beyers, M, Blunn, L, Boussetta, S, Bou-Zeid, E, De Kauwe, MG, de Munck, C, Demuzere, M, Fatichi, S, Fortuniak, K, Han, BS, Hendry, MA, Kikegawa, Y, Kondo, H, Lee, DI, Lee, SH, Lemonsu, A, Machado, T, Manoli, G, Martilli, A, Masson, V, McNorton, J, Meili, N, Meyer, D, Nice, KA, Oleson, KW, Park, SB, Roth, M, Schoetter, R, Simón-Moral, A, Steeneveld, GJ, Sun, T, Takane, Y, Thatcher, M, Tsiringakis, A, Varentsov, M, Wang, C, Wang, ZH & Pitman, AJ 2024, 'Evaluation of 30 urban land surface models in the Urban-PLUMBER project: Phase 1 results', Quarterly Journal of the Royal Meteorological Society, vol. 150, no. 758, pp. 126-169. https://doi.org/10.1002/qj.4589

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title = "Evaluation of 30 urban land surface models in the Urban-PLUMBER project: Phase 1 results",

abstract = "Accurately predicting weather and climate in cities is critical for safeguarding human health and strengthening urban resilience. Multimodel evaluations can lead to model improvements; however, there have been no major intercomparisons of urban-focussed land surface models in over a decade. Here, in Phase 1 of the Urban-PLUMBER project, we evaluate the ability of 30 land surface models to simulate surface energy fluxes critical to atmospheric meteorological and air quality simulations. We establish minimum and upper performance expectations for participating models using simple information-limited models as benchmarks. Compared with the last major model intercomparison at the same site, we find broad improvement in the current cohort's predictions of short-wave radiation, sensible and latent heat fluxes, but little or no improvement in long-wave radiation and momentum fluxes. Models with a simple urban representation (e.g., {\textquoteleft}slab{\textquoteright} schemes) generally perform well, particularly when combined with sophisticated hydrological/vegetation models. Some mid-complexity models (e.g., {\textquoteleft}canyon{\textquoteright} schemes) also perform well, indicating efforts to integrate vegetation and hydrology processes have paid dividends. The most complex models that resolve three-dimensional interactions between buildings in general did not perform as well as other categories. However, these models also tended to have the simplest representations of hydrology and vegetation. Models without any urban representation (i.e., vegetation-only land surface models) performed poorly for latent heat fluxes, and reasonably for other energy fluxes at this suburban site. Our analysis identified widespread human errors in initial submissions that substantially affected model performances. Although significant efforts are applied to correct these errors, we conclude that human factors are likely to influence results in this (or any) model intercomparison, particularly where participating scientists have varying experience and first languages. These initial results are for one suburban site, and future phases of Urban-PLUMBER will evaluate models across 20 sites in different urban and regional climate zones.",

keywords = "benchmark, energy balance, intercomparison, model evaluation, urban climate, urban meteorology",

author = "Lipson, {Mathew J.} and Sue Grimmond and Martin Best and Gab Abramowitz and Andrew Coutts and Nigel Tapper and Baik, {Jong Jin} and Meiring Beyers and Lewis Blunn and Souhail Boussetta and Elie Bou-Zeid and {De Kauwe}, {Martin G.} and {de Munck}, C{\'e}cile and Matthias Demuzere and Simone Fatichi and Krzysztof Fortuniak and Han, {Beom Soon} and Hendry, {Margaret A.} and Yukihiro Kikegawa and Hiroaki Kondo and Lee, {Doo Il} and Lee, {Sang Hyun} and Aude Lemonsu and Tiago Machado and Gabriele Manoli and Alberto Martilli and Val{\'e}ry Masson and Joe McNorton and Naika Meili and David Meyer and Nice, {Kerry A.} and Oleson, {Keith W.} and Park, {Seung Bu} and Michael Roth and Robert Schoetter and Andr{\'e}s Sim{\'o}n-Moral and Steeneveld, {Gert Jan} and Ting Sun and Yuya Takane and Marcus Thatcher and Aristofanis Tsiringakis and Mikhail Varentsov and Chenghao Wang and Wang, {Zhi Hua} and Pitman, {Andy J.}",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors. Quarterly Journal of the Royal Meteorological Society published by John Wiley & Sons Ltd on behalf of the Royal Meteorological Society.",

year = "2024",

month = jan,

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doi = "10.1002/qj.4589",

language = "English (US)",

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pages = "126--169",

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T1 - Evaluation of 30 urban land surface models in the Urban-PLUMBER project

T2 - Phase 1 results

AU - Lipson, Mathew J.

AU - Grimmond, Sue

AU - Best, Martin

AU - Abramowitz, Gab

AU - Coutts, Andrew

AU - Tapper, Nigel

AU - Baik, Jong Jin

AU - Beyers, Meiring

AU - Blunn, Lewis

AU - Boussetta, Souhail

AU - Bou-Zeid, Elie

AU - De Kauwe, Martin G.

AU - de Munck, Cécile

AU - Demuzere, Matthias

AU - Fatichi, Simone

AU - Fortuniak, Krzysztof

AU - Han, Beom Soon

AU - Hendry, Margaret A.

AU - Kikegawa, Yukihiro

AU - Kondo, Hiroaki

AU - Lee, Doo Il

AU - Lee, Sang Hyun

AU - Lemonsu, Aude

AU - Machado, Tiago

AU - Manoli, Gabriele

AU - Martilli, Alberto

AU - Masson, Valéry

AU - McNorton, Joe

AU - Meili, Naika

AU - Meyer, David

AU - Nice, Kerry A.

AU - Oleson, Keith W.

AU - Park, Seung Bu

AU - Roth, Michael

AU - Schoetter, Robert

AU - Simón-Moral, Andrés

AU - Steeneveld, Gert Jan

AU - Sun, Ting

AU - Takane, Yuya

AU - Thatcher, Marcus

AU - Tsiringakis, Aristofanis

AU - Varentsov, Mikhail

AU - Wang, Chenghao

AU - Wang, Zhi Hua

AU - Pitman, Andy J.

PY - 2024/1/1

Y1 - 2024/1/1

N2 - Accurately predicting weather and climate in cities is critical for safeguarding human health and strengthening urban resilience. Multimodel evaluations can lead to model improvements; however, there have been no major intercomparisons of urban-focussed land surface models in over a decade. Here, in Phase 1 of the Urban-PLUMBER project, we evaluate the ability of 30 land surface models to simulate surface energy fluxes critical to atmospheric meteorological and air quality simulations. We establish minimum and upper performance expectations for participating models using simple information-limited models as benchmarks. Compared with the last major model intercomparison at the same site, we find broad improvement in the current cohort's predictions of short-wave radiation, sensible and latent heat fluxes, but little or no improvement in long-wave radiation and momentum fluxes. Models with a simple urban representation (e.g., ‘slab’ schemes) generally perform well, particularly when combined with sophisticated hydrological/vegetation models. Some mid-complexity models (e.g., ‘canyon’ schemes) also perform well, indicating efforts to integrate vegetation and hydrology processes have paid dividends. The most complex models that resolve three-dimensional interactions between buildings in general did not perform as well as other categories. However, these models also tended to have the simplest representations of hydrology and vegetation. Models without any urban representation (i.e., vegetation-only land surface models) performed poorly for latent heat fluxes, and reasonably for other energy fluxes at this suburban site. Our analysis identified widespread human errors in initial submissions that substantially affected model performances. Although significant efforts are applied to correct these errors, we conclude that human factors are likely to influence results in this (or any) model intercomparison, particularly where participating scientists have varying experience and first languages. These initial results are for one suburban site, and future phases of Urban-PLUMBER will evaluate models across 20 sites in different urban and regional climate zones.

AB - Accurately predicting weather and climate in cities is critical for safeguarding human health and strengthening urban resilience. Multimodel evaluations can lead to model improvements; however, there have been no major intercomparisons of urban-focussed land surface models in over a decade. Here, in Phase 1 of the Urban-PLUMBER project, we evaluate the ability of 30 land surface models to simulate surface energy fluxes critical to atmospheric meteorological and air quality simulations. We establish minimum and upper performance expectations for participating models using simple information-limited models as benchmarks. Compared with the last major model intercomparison at the same site, we find broad improvement in the current cohort's predictions of short-wave radiation, sensible and latent heat fluxes, but little or no improvement in long-wave radiation and momentum fluxes. Models with a simple urban representation (e.g., ‘slab’ schemes) generally perform well, particularly when combined with sophisticated hydrological/vegetation models. Some mid-complexity models (e.g., ‘canyon’ schemes) also perform well, indicating efforts to integrate vegetation and hydrology processes have paid dividends. The most complex models that resolve three-dimensional interactions between buildings in general did not perform as well as other categories. However, these models also tended to have the simplest representations of hydrology and vegetation. Models without any urban representation (i.e., vegetation-only land surface models) performed poorly for latent heat fluxes, and reasonably for other energy fluxes at this suburban site. Our analysis identified widespread human errors in initial submissions that substantially affected model performances. Although significant efforts are applied to correct these errors, we conclude that human factors are likely to influence results in this (or any) model intercomparison, particularly where participating scientists have varying experience and first languages. These initial results are for one suburban site, and future phases of Urban-PLUMBER will evaluate models across 20 sites in different urban and regional climate zones.

KW - benchmark

KW - energy balance

KW - intercomparison

KW - model evaluation

KW - urban climate

KW - urban meteorology

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Evaluation of 30 urban land surface models in the Urban-PLUMBER project: Phase 1 results

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