Editorial Type:
Article
Article Type:
Research Article

Daytime Boundary Layer Evolution in a Deep Valley. Part II: Numerical Simulation of the Cross-Valley Circulation

Tsuneo Kuwagata Tohoku National Agricultural Experiment Station, Morioka, Japan

Search for other papers by Tsuneo Kuwagata in
Current site
Google Scholar
PubMed Close
and
Fujio Kimura Institute of Geoscience, Tsukuba University, Tsukuba, Ibaraki, Japan

Search for other papers by Fujio Kimura in
Current site
Google Scholar
PubMed Close
Print Publication:
01 Jul 1997
DOI:
https://doi.org/10.1175/1520-0450(1997)036<0883:DBLEIA>2.0.CO;2
Page(s):
883–895
Restricted access

Abstract

The thermally induced circulation in a deep valley during fair weather and weak synoptic wind conditions is simulated by a two-dimensional numerical model, in order to investigate the daytime planetary boundary layer evolution observed in the Ina Valley, a deep, two-dimensional valley in Japan. The numerical model can simulate the observed structure of the PBL fairly well, along with the daytime variations of the observed valley surface air temperature and surface pressure.

The numerical simulations suggest that the thermally induced cross-valley circulation creates a two-layer PBL structure. That is, a turbulent mixed layer develops due to sensible heating from the surface, reaching to heights of about 500–1000 m above the valley floor, while a quasi–mixed layer is formed above the turbulent mixed layer by the heat transport of the cross-valley circulation. The quasi–mixed layer is a new feature of the PBL. The upper limit of the quasi–mixed layer corresponds to the top of the cross-valley circulation, being somewhat higher than both sides of the mountains. The quasi–mixed layer can be clearly distinguished during the daytime in a deep valley having a depth of greater than about 1500 m. Since the quasi–mixed layer has a slightly stable stratification, the magnitude of the coefficient of vertical turbulence in this layer is much less than that in the turbulent mixed layer.

The results of the simulations reveal that the thermally induced cross-valley circulation transports heat from the mountainous regions to the central part of the valley, while water vapor is transported in the opposite manner. The potential temperature becomes horizontally uniform during the afternoon, except in the shallow layer of the upslope flow along the side slopes. On the other hand, the daytime distribution of specific humidity in the valley is rather complex, being affected not only by the cross-valley circulation, but also by the ambient wind along the direction of the cross valley. Water vapor tends to be accumulated over the mountainous regions during the daytime, resulting in the formation of cumulus clouds. Visible images observed by the NOAA satellite confirm the development of cumulus clouds over the mountainous regions in the Ina Valley during the afternoon.

Corresponding authoraddress: Dr. Tsuneo Kuwagata, Tohoku National Agricultural Experiment Station, 4 Akahira, Shimo-Kuriyagawa, Morioka 020-01, Japan.

Abstract

The thermally induced circulation in a deep valley during fair weather and weak synoptic wind conditions is simulated by a two-dimensional numerical model, in order to investigate the daytime planetary boundary layer evolution observed in the Ina Valley, a deep, two-dimensional valley in Japan. The numerical model can simulate the observed structure of the PBL fairly well, along with the daytime variations of the observed valley surface air temperature and surface pressure.

The numerical simulations suggest that the thermally induced cross-valley circulation creates a two-layer PBL structure. That is, a turbulent mixed layer develops due to sensible heating from the surface, reaching to heights of about 500–1000 m above the valley floor, while a quasi–mixed layer is formed above the turbulent mixed layer by the heat transport of the cross-valley circulation. The quasi–mixed layer is a new feature of the PBL. The upper limit of the quasi–mixed layer corresponds to the top of the cross-valley circulation, being somewhat higher than both sides of the mountains. The quasi–mixed layer can be clearly distinguished during the daytime in a deep valley having a depth of greater than about 1500 m. Since the quasi–mixed layer has a slightly stable stratification, the magnitude of the coefficient of vertical turbulence in this layer is much less than that in the turbulent mixed layer.

The results of the simulations reveal that the thermally induced cross-valley circulation transports heat from the mountainous regions to the central part of the valley, while water vapor is transported in the opposite manner. The potential temperature becomes horizontally uniform during the afternoon, except in the shallow layer of the upslope flow along the side slopes. On the other hand, the daytime distribution of specific humidity in the valley is rather complex, being affected not only by the cross-valley circulation, but also by the ambient wind along the direction of the cross valley. Water vapor tends to be accumulated over the mountainous regions during the daytime, resulting in the formation of cumulus clouds. Visible images observed by the NOAA satellite confirm the development of cumulus clouds over the mountainous regions in the Ina Valley during the afternoon.

Corresponding authoraddress: Dr. Tsuneo Kuwagata, Tohoku National Agricultural Experiment Station, 4 Akahira, Shimo-Kuriyagawa, Morioka 020-01, Japan.

Save
Cover Journal of Applied Meteorology and Climatology
Journal of Applied Meteorology and Climatology

  • Bader, D. C., and T. B. McKee, 1983: Dynamic model of the morning boundary layer development in deep mountain valleys. J. Climate Appl. Meteor.,22, 341–351.

  • ——, and ——, 1985: Effects of shear, stability and valley characteristics on the destruction of temperature inversions. J. Climate Appl. Meteor.,24, 822–832.

  • Bossert, J. E., and W. R. Cotton, 1994a: Regional-scale flows in mountainous terrain. Part I: A numerical and observational comparison. Mon. Wea. Rev.,122, 1449–1471.

  • ——, and ——, 1994b: Regional-scale flows in mountainous terrain. Part II: Simplified numerical experiments. Mon. Wea. Rev.,122, 1472–1489.

  • Bougeault, P., 1983: A non-reflective upper boundary condition for limited-height hydrostatic models. Mon. Wea. Rev.,111, 420–429.

  • Kikuchi, Y., S. Arakawa, F. Kimura, K. Shirasaki, and Y. Nagano, 1981: Numerical study on the effects of on the land and sea breeze circulation in the Kanto District. J. Meteor. Soc. Japan,59, 723–738.

  • Kimura, F., and S. Arakawa, 1983: A numerical experiment of the nocturnal low level jet over the Kanto Plain. J. Meteor. Soc. Japan,61, 848–861.

  • ——, and P. Manins, 1988: Blocking in periodic valleys. Bound.-Layer Meteor.,44, 137–169.

  • ——, and T. Kuwagata, 1993: Thermally induced wind passing from plain to basin over a mountain range. J. Appl. Meteor.,32, 1538–1547.

  • ——, and ——, 1995: Horizontal heat fluxes over a complex terrain computed using a simple mixed-layer model and a numerical model. J. Appl. Meteor.,34, 549–558.

  • Klemp, J. B., and D. R. Durran, 1983: An upper boundary condition permitting internal gravity wave radiation in numerical mesoscale models. Mon. Wea. Rev.,111, 430–444.

  • Kondo, J., T. Kuwagata, and S. Haginoya, 1989: Heat budget analysis of nocturnal cooling and daytime heating in a basin. J. Atmos. Sci.,46, 2917–2933.

  • Kuwagata, T., and F. Kimura, 1995: Daytime boundary layer evolution in a deep valley. Part I: Observations in the Ina Valley. J. Appl. Meteor.,34, 1082–1091.

  • ——, M. Sumioka, N. Masuko, and J. Kondo, 1990a: The daytime PBL heating process over complex terrain in central Japan under fair and calm weather conditions: Part I. Meso-scale circulation and the PBL heating rate. J. Meteor. Soc. Japan,68, 625–638.

  • ——, N. Masuko, M. Sumioka, and J. Kondo, 1990b: The daytime PBL heating process over complex terrain in central Japan under fair and calm weather conditions. Part II: Regional heat budget, convective boundary layer height and surface moisture availability. J. Meteor. Soc. Japan,68, 639–650.

  • Mellor, G. L., and T. Yamada, 1974: A hierarchy of turbulence closure models of planetary boundary layers. J. Atmos. Sci.,31, 1791–1805.

  • Müller, H., and C. D. Whiteman, 1988: Breakup of a nocturnal temperature inversion in the Dischma Valley during DISKUS. J. Appl. Meteor.,27, 188–194.

  • Pielke, R. A., 1984:Mesoscale Meteorological Modeling. Academic Press, 612 pp.

  • Sakiyama, S. K., 1990: Drainage flow characteristics and inversion breakup in two Alberta mountain valleys. J. Appl. Meteor.,29, 1015–1030.

  • Walko, R. L., W. R. Cotton, and R. A. Pielke, 1992: Large-eddy simulation of the effects of hilly terrain on the convective boundary layer. Bound.-Layer Meteor.,58, 133–150.

  • Whiteman, C. D., 1982: Breakup of temperature inversions in deep mountain valleys: Part I. Observations. J. Appl. Meteor.,21, 270–289.

  • ——, and T. B. McKee, 1982: Breakup of temperature inversions in deep mountain valleys: Part II. Thermodynamic model. J. Appl. Meteor.,21, 290–302.

All Time Past Year Past 30 Days
Abstract Views 0 0 0
Full Text Views 835 475 16
PDF Downloads 182 48 3