Editorial Type:
Article
Article Type:
Research Article

A Climatological Study of Internal Gravity Waves in the Atmospheric Boundary Layer Overlying the Brunt Ice Shelf, Antarctica

J. M. Rees School of Mathematics and Statistics, University of Sheffield, Sheffield, United Kingdom

Search for other papers by J. M. Rees in
Current site
Google Scholar
PubMed Close
,
J. C. W. Denholm-Price School of Mathematics and Statistics, University of Sheffield, Sheffield, United Kingdom

Search for other papers by J. C. W. Denholm-Price in
Current site
Google Scholar
PubMed Close
,
J. C. King British Antarctic Survey, Natural Environment Research Council, Cambridge, United Kingdom

Search for other papers by J. C. King in
Current site
Google Scholar
PubMed Close
, and
P. S. Anderson British Antarctic Survey, Natural Environment Research Council, Cambridge, United Kingdom

Search for other papers by P. S. Anderson in
Current site
Google Scholar
PubMed Close
Print Publication:
01 Feb 2000
DOI:
https://doi.org/10.1175/1520-0469(2000)057<0511:ACSOIG>2.0.CO;2
Page(s):
511–526
Restricted access

Abstract

Internal gravity waves are frequently observed in stably stratified regions of the atmospheric boundary layer. In order to determine the statistical influence of such waves on the dynamics of the boundary layer it is necessary to compile information concerning properties of the waves such as frequency of occurrence, propagation, and spectral characteristics. Gravity wave climatologies have been compiled from relatively few locations. In this paper a climatological study of gravity waves, in the period range 1–20 min, propagating in the stably stratified atmospheric boundary layer overlying an Antarctic ice shelf is presented. An extensive set of boundary layer measurements were compiled throughout 1991. Surface pressure fluctuations were recorded from a spatial array of six sensitive microbarographs. Wind and temperature records from an instrumented mast were also available. A beam-steering technique has been used to determine wave parameters from the surface pressure data. The microbarographs detected the presence of internal gravity waves throughout the observational campaign. Root-mean-square pressure values were typically in the region 16–40 μb, but a significant number of isolated events with amplitudes of up to 180 μb were also found. Wave properties have been studied in conjunction with the mean wind and temperature profiles in the boundary layer. It was found that most of the wave activity did not originate locally, but from shear layers aloft, or, more commonly, from the katabatic flow regime where the ice shelf joins the Antarctic continent.

* Current affiliation: School of Mathematics, Kingston University, Kingston upon Thames, United Kingdom.

Corresponding author address: Dr. Julia M. Rees, School of Mathematics and Statistics, Hicks Building, Hounsfield Road, University of Sheffield, Sheffield S3 7RH, United Kingdom.

Abstract

Internal gravity waves are frequently observed in stably stratified regions of the atmospheric boundary layer. In order to determine the statistical influence of such waves on the dynamics of the boundary layer it is necessary to compile information concerning properties of the waves such as frequency of occurrence, propagation, and spectral characteristics. Gravity wave climatologies have been compiled from relatively few locations. In this paper a climatological study of gravity waves, in the period range 1–20 min, propagating in the stably stratified atmospheric boundary layer overlying an Antarctic ice shelf is presented. An extensive set of boundary layer measurements were compiled throughout 1991. Surface pressure fluctuations were recorded from a spatial array of six sensitive microbarographs. Wind and temperature records from an instrumented mast were also available. A beam-steering technique has been used to determine wave parameters from the surface pressure data. The microbarographs detected the presence of internal gravity waves throughout the observational campaign. Root-mean-square pressure values were typically in the region 16–40 μb, but a significant number of isolated events with amplitudes of up to 180 μb were also found. Wave properties have been studied in conjunction with the mean wind and temperature profiles in the boundary layer. It was found that most of the wave activity did not originate locally, but from shear layers aloft, or, more commonly, from the katabatic flow regime where the ice shelf joins the Antarctic continent.

* Current affiliation: School of Mathematics, Kingston University, Kingston upon Thames, United Kingdom.

Corresponding author address: Dr. Julia M. Rees, School of Mathematics and Statistics, Hicks Building, Hounsfield Road, University of Sheffield, Sheffield S3 7RH, United Kingdom.

Save
Cover Journal of the Atmospheric Sciences
Journal of the Atmospheric Sciences

  • Anderson, P. S., S. D. Mobbs, J. C. King, I. McConnell, and J. M. Rees, 1992: A microbarograph for internal gravity wave studies in Antarctica. J. Antarct. Sci.,4, 241–248.

  • Bull, G., R. Dubois, J. Neisser, and J. G. Stangenberg, 1981: Untersuchungen uber Schwerewellen in Gebirgshe. Z. Meteor.,31, 267–279.

  • Capon, J., 1969: High-resolution frequency-wavenumber spectrum analysis. Proc. IEEE,57, 1408–1416.

  • Cheung, T. K., and C. G. Little, 1990: Meteorological tower, microbarograph array, and sodar observations of solitary-like waves in the nocturnal boundary layer. J. Atmos. Sci.,47, 2516–2536.

  • Denholm-Price, J. C. W., and J. M. Rees, 1998: A practical example of low-frequency trend removal. Bound.-Layer Meteor.,86, 181–187.

  • ——, and ——, 1999: Detecting waves using an array of sensors. Mon. Wea. Rev.,127, 57–69.

  • Egger, J., C. Wamser, and C. Kottmeier, 1993: Internal atmospheric gravity waves near the coast of Antarctica. Bound.-Layer Meteor.,66, 1–17.

  • Einaudi, F., A. J. Bedard, and J. J. Finnigan, 1989: A climatology of gravity waves and other coherent disturbances at the Boulder Atmospheric Observatory during March–April 1984. J. Atmos. Sci.,46, 303–329.

  • Gedzelman, S. D., 1983: Short-period atmospheric gravity waves: A study of their statistical properties and source mechanisms. Mon. Wea. Rev.,111, 1293–1299.

  • Haubrich, R. A., 1968: Array design. Bull. Seismol. Soc. Amer.,58, 977–991.

  • Hauf, T., U. Finke, J. Neisser, G. Bull, and J.-G. Stangenberg, 1996:A ground-based network for atmospheric pressure fluctuations. J. Atmos. Oceanic Technol.,13, 1001–1023.

  • Hooke, W. H., J. M. Young, and D. W. Beran, 1972: Atmospheric waves observed in the planetary boundary layer using an acoustic sounder and a microbarograph array. Bound.-Layer Meteor.,2, 371–380.

  • Keliher, T. E., 1975: The occurrence of microbarograph-detected gravity waves compared with the existence of dynamically unstable wind shear layers. J. Geophys. Res.,80, 2967–2976.

  • Kikuchi, T., 1988: A case study of a wave-like cloud and gravity wave in the lower troposphere in Mizuho Plateau Antarctica. Bound.-Layer Meteor.,43, 403–409.

  • King, J. C., 1989: Low-level wind profiles at an Antarctic coastal station. J. Antarct. Sci.,1, 169–178.

  • ——, 1990: Some measurements of turbulence over an Antarctic ice shelf. Quart. J. Roy. Meteor. Soc.,116, 379–400.

  • ——, 1993: Control of near-surface winds over an Antarctic ice shelf. J. Geophys. Res.,98, 12 949–12 953.

  • ——, S. D. Mobbs, M. S. Darby, and J. M. Rees, 1987: Observations of an internal gravity wave in the lower troposphere at Halley, Antarctica. Bound.-Layer Meteor.,39, 1–13.

  • ——, ——, J. M. Rees, P. S. Anderson, and A. D. Culf, 1989: The Stable Antarctic Boundary Layer Experiment at Halley Base. Weather,44, 398–405.

  • Merrill, J. T., 1977: Observational and theoretical study of shear instability in the airflow near the ground. J. Atmos. Sci.,34, 911–921.

  • Rees, J. M., 1987: The propagation of internal gravity waves in the stably stratified atmospheric boundary layer. Ann. Geophys.,5B, 421–432.

  • ——, 1991: On the characteristics of eddies in the stable atmospheric boundary layer. Bound.-Layer Meteor.,55, 325–343.

  • ——, and S. D. Mobbs, 1988: Studies of internal gravity waves at Halley Station, Antarctica, using wind observations. Quart. J. Roy. Meteor. Soc.,114, 939–966.

  • Smart, E., and E. A. Flinn, 1971: Fast frequency-wavenumber analysis and Fisher signal detection in real-time infrasonic array data processing. Geophys. J. Roy. Astrophys. Sci.,26, 279–284.

  • Yägue, C., and J. L. Cano, 1994: The influence of stratification on heat and momentum transfer in Antarctica. Bound.-Layer Meteor.,69, 123–136.

All Time Past Year Past 30 Days
Abstract Views 0 0 0
Full Text Views 1965 1319 54
PDF Downloads 277 71 3