A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains

Mathias W. Rotach; Stefano Serafin; Helen C. Ward; Marco Arpagaus; Ioana Colfescu; Joan Cuxart; Stephan F.J. De Wekker; Vanda Grubišic; Norbert Kalthoff; Thomas Karl; Daniel J. Kirshbaum; Manuela Lehner; Stephen Mobbs; Alexandre Paci; Elisa Palazzi; Adriana Bailey; Jürg Schmidli; Christoph Wittmann; Georg Wohlfahrt; Dino Zardi

doi:10.1175/BAMS-D-21-0232.1

A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains

Mathias W. Rotach^*, Stefano Serafin, Helen C. Ward, Marco Arpagaus, Ioana Colfescu, Joan Cuxart, Stephan F.J. De Wekker, Vanda Grubišic, Norbert Kalthoff, Thomas Karl, Daniel J. Kirshbaum, Manuela Lehner, Stephen Mobbs, Alexandre Paci, Elisa Palazzi, Adriana Bailey, Jürg Schmidli, Christoph Wittmann, Georg Wohlfahrt, Dino Zardi

^*Corresponding author for this work

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

Abstract

In this essay, we highlight some challenges the atmospheric community is facing concerning adequate treatment of flows over mountains and their implications for numerical weather prediction (NWP), climate simulations, and impact modeling. With recent increases in computing power (and hence model resolution) numerical models start to face new limitations (such as numerical instability over steep terrain). At the same time there is a growing need for sufficiently reliable NWP model output to drive various impact models (for hydrology, air pollution, agriculture, etc.). The input information for these impact models is largely produced by the boundary layer (BL) parameterizations of NWP models. All known BL parameterizations assume flat and horizontally homogeneous surface conditions, and their performance and interaction with resolved flows is massively understudied over mountains-hence their output may be accidentally acceptable at best. We therefore advocate the systematic investigation of the so-called "mountain boundary layer"(MoBL), introduced to emphasize its many differences to the BL over flat and horizontally homogeneous terrain. An international consortium of scientists has launched a research program, TEAMx (Multi-Scale Transport and Exchange Processes in the Atmosphere over Mountains-Program and Experiment), to address some of the most pressing scientific challenges. TEAMx is endorsed by World Weather Research Programme (WWRP) and the Global Energy and Water Exchanges (GEWEX) project as a "cross-cutting project."A program coordination office was established at the University of Innsbruck (Austria). This essay introduces the background to and content of a recently published white paper outlining the key research questions of TEAMx.

Original language	English
Pages (from-to)	E1282-E1295
Journal	Bulletin of the American Meteorological Society
Volume	103
Issue number	5
DOIs	https://doi.org/10.1175/BAMS-D-21-0232.1
Publication status	Published - 1 May 2022

Keywords

Climate prediction
Mass fluxes/transport
Mesoscale processes
Orographic effects
Topographic effects
Turbulence

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1175/BAMS-D-21-0232.1

Cite this

Rotach, M. W., Serafin, S., Ward, H. C., Arpagaus, M., Colfescu, I., Cuxart, J., De Wekker, S. F. J., Grubišic, V., Kalthoff, N., Karl, T., Kirshbaum, D. J., Lehner, M., Mobbs, S., Paci, A., Palazzi, E., Bailey, A., Schmidli, J., Wittmann, C., Wohlfahrt, G., & Zardi, D. (2022). A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains. Bulletin of the American Meteorological Society, 103(5), E1282-E1295. https://doi.org/10.1175/BAMS-D-21-0232.1

@article{269cc93a393f45e98139e35a8f6a1869,

title = "A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains",

abstract = "In this essay, we highlight some challenges the atmospheric community is facing concerning adequate treatment of flows over mountains and their implications for numerical weather prediction (NWP), climate simulations, and impact modeling. With recent increases in computing power (and hence model resolution) numerical models start to face new limitations (such as numerical instability over steep terrain). At the same time there is a growing need for sufficiently reliable NWP model output to drive various impact models (for hydrology, air pollution, agriculture, etc.). The input information for these impact models is largely produced by the boundary layer (BL) parameterizations of NWP models. All known BL parameterizations assume flat and horizontally homogeneous surface conditions, and their performance and interaction with resolved flows is massively understudied over mountains-hence their output may be accidentally acceptable at best. We therefore advocate the systematic investigation of the so-called {"}mountain boundary layer{"}(MoBL), introduced to emphasize its many differences to the BL over flat and horizontally homogeneous terrain. An international consortium of scientists has launched a research program, TEAMx (Multi-Scale Transport and Exchange Processes in the Atmosphere over Mountains-Program and Experiment), to address some of the most pressing scientific challenges. TEAMx is endorsed by World Weather Research Programme (WWRP) and the Global Energy and Water Exchanges (GEWEX) project as a {"}cross-cutting project.{"}A program coordination office was established at the University of Innsbruck (Austria). This essay introduces the background to and content of a recently published white paper outlining the key research questions of TEAMx.",

keywords = "Climate prediction, Mass fluxes/transport, Mesoscale processes, Orographic effects, Topographic effects, Turbulence",

author = "Rotach, {Mathias W.} and Stefano Serafin and Ward, {Helen C.} and Marco Arpagaus and Ioana Colfescu and Joan Cuxart and {De Wekker}, {Stephan F.J.} and Vanda Grubi{\v s}ic and Norbert Kalthoff and Thomas Karl and Kirshbaum, {Daniel J.} and Manuela Lehner and Stephen Mobbs and Alexandre Paci and Elisa Palazzi and Adriana Bailey and J{\"u}rg Schmidli and Christoph Wittmann and Georg Wohlfahrt and Dino Zardi",

note = "TEMAx is bottom-up funded, so each TEAMx project has its own source. The project coordination office at the University of Innsbruck is financially supported by the following institutions (in alphabetical order): Center for Climate Systems Modeling (https://c2sm.ethz.ch); Consortium for Small-scale Modeling (COSMO; www.cosmo-model.org); F{\"o}rderkreis 1669 (www.uibk.ac.at/de/ foerderkreis1669/); Karlsruhe Institute of Technology (www.kit.edu/english/index.php); Meteo France (https:// meteofrance.com); MeteoSwiss (www.meteoswiss.admin.ch/home.html?tab=overview); National Centre for Atmospheric Science (UK; https://ncas.ac.uk); University of Innsbruck (www.uibk.ac.at/en/); University of Trento (www.unitn.it/en); and ZAMG (www.zamg.ac.at/cms/de/aktuell).",

year = "2022",

month = may,

day = "1",

doi = "10.1175/BAMS-D-21-0232.1",

language = "English",

volume = "103",

pages = "E1282--E1295",

journal = "Bulletin of the American Meteorological Society",

issn = "0003-0007",

publisher = "American Meteorological Society",

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Rotach, MW, Serafin, S, Ward, HC, Arpagaus, M, Colfescu, I, Cuxart, J, De Wekker, SFJ, Grubišic, V, Kalthoff, N, Karl, T, Kirshbaum, DJ, Lehner, M, Mobbs, S, Paci, A, Palazzi, E, Bailey, A, Schmidli, J, Wittmann, C, Wohlfahrt, G & Zardi, D 2022, 'A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains', Bulletin of the American Meteorological Society, vol. 103, no. 5, pp. E1282-E1295. https://doi.org/10.1175/BAMS-D-21-0232.1

TY - JOUR

T1 - A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains

AU - Rotach, Mathias W.

AU - Serafin, Stefano

AU - Ward, Helen C.

AU - Arpagaus, Marco

AU - Colfescu, Ioana

AU - Cuxart, Joan

AU - De Wekker, Stephan F.J.

AU - Grubišic, Vanda

AU - Kalthoff, Norbert

AU - Karl, Thomas

AU - Kirshbaum, Daniel J.

AU - Lehner, Manuela

AU - Mobbs, Stephen

AU - Paci, Alexandre

AU - Palazzi, Elisa

AU - Bailey, Adriana

AU - Schmidli, Jürg

AU - Wittmann, Christoph

AU - Wohlfahrt, Georg

AU - Zardi, Dino

N1 - TEMAx is bottom-up funded, so each TEAMx project has its own source. The project coordination office at the University of Innsbruck is financially supported by the following institutions (in alphabetical order): Center for Climate Systems Modeling (https://c2sm.ethz.ch); Consortium for Small-scale Modeling (COSMO; www.cosmo-model.org); Förderkreis 1669 (www.uibk.ac.at/de/ foerderkreis1669/); Karlsruhe Institute of Technology (www.kit.edu/english/index.php); Meteo France (https:// meteofrance.com); MeteoSwiss (www.meteoswiss.admin.ch/home.html?tab=overview); National Centre for Atmospheric Science (UK; https://ncas.ac.uk); University of Innsbruck (www.uibk.ac.at/en/); University of Trento (www.unitn.it/en); and ZAMG (www.zamg.ac.at/cms/de/aktuell).

PY - 2022/5/1

Y1 - 2022/5/1

N2 - In this essay, we highlight some challenges the atmospheric community is facing concerning adequate treatment of flows over mountains and their implications for numerical weather prediction (NWP), climate simulations, and impact modeling. With recent increases in computing power (and hence model resolution) numerical models start to face new limitations (such as numerical instability over steep terrain). At the same time there is a growing need for sufficiently reliable NWP model output to drive various impact models (for hydrology, air pollution, agriculture, etc.). The input information for these impact models is largely produced by the boundary layer (BL) parameterizations of NWP models. All known BL parameterizations assume flat and horizontally homogeneous surface conditions, and their performance and interaction with resolved flows is massively understudied over mountains-hence their output may be accidentally acceptable at best. We therefore advocate the systematic investigation of the so-called "mountain boundary layer"(MoBL), introduced to emphasize its many differences to the BL over flat and horizontally homogeneous terrain. An international consortium of scientists has launched a research program, TEAMx (Multi-Scale Transport and Exchange Processes in the Atmosphere over Mountains-Program and Experiment), to address some of the most pressing scientific challenges. TEAMx is endorsed by World Weather Research Programme (WWRP) and the Global Energy and Water Exchanges (GEWEX) project as a "cross-cutting project."A program coordination office was established at the University of Innsbruck (Austria). This essay introduces the background to and content of a recently published white paper outlining the key research questions of TEAMx.

AB - In this essay, we highlight some challenges the atmospheric community is facing concerning adequate treatment of flows over mountains and their implications for numerical weather prediction (NWP), climate simulations, and impact modeling. With recent increases in computing power (and hence model resolution) numerical models start to face new limitations (such as numerical instability over steep terrain). At the same time there is a growing need for sufficiently reliable NWP model output to drive various impact models (for hydrology, air pollution, agriculture, etc.). The input information for these impact models is largely produced by the boundary layer (BL) parameterizations of NWP models. All known BL parameterizations assume flat and horizontally homogeneous surface conditions, and their performance and interaction with resolved flows is massively understudied over mountains-hence their output may be accidentally acceptable at best. We therefore advocate the systematic investigation of the so-called "mountain boundary layer"(MoBL), introduced to emphasize its many differences to the BL over flat and horizontally homogeneous terrain. An international consortium of scientists has launched a research program, TEAMx (Multi-Scale Transport and Exchange Processes in the Atmosphere over Mountains-Program and Experiment), to address some of the most pressing scientific challenges. TEAMx is endorsed by World Weather Research Programme (WWRP) and the Global Energy and Water Exchanges (GEWEX) project as a "cross-cutting project."A program coordination office was established at the University of Innsbruck (Austria). This essay introduces the background to and content of a recently published white paper outlining the key research questions of TEAMx.

KW - Climate prediction

KW - Mass fluxes/transport

KW - Mesoscale processes

KW - Orographic effects

KW - Topographic effects

KW - Turbulence

U2 - 10.1175/BAMS-D-21-0232.1

DO - 10.1175/BAMS-D-21-0232.1

M3 - Article

AN - SCOPUS:85131596576

SN - 0003-0007

VL - 103

SP - E1282-E1295

JO - Bulletin of the American Meteorological Society

JF - Bulletin of the American Meteorological Society

IS - 5

ER -

A collaborative effort to better understand, measure, and model atmospheric exchange processes over mountains

Abstract

Keywords

UN SDGs

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