Abstract
This historical survey shows that Obukhov’s 1946 fundamental paper on a universal length scale for exchange processes in the surface layer was the basis for the derivation of the similarity theory by Monin and Obukhov in 1954. A brief overview of the experiments and findings used to formulate the universal functions in the presently used form is given. Finally, the current status of the theory is described, covering topics such as the accuracy of the universal functions and the turbulent Prandtl number.
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Albrecht, F.: 1940, ‘Untersuchungen über den Wärmehaushalt der Erdoberfläche in verschiedenen Klimagebieten’, Reichsamt f. Wetterdienst, Wiss. Abh. Bd. VIII, Nr. 2, 1–82.
Andreas, E. L., Claffey, K. J., Fairall, C. W., Grachev, A. A., Guest, P. S., Jordan, R. E., and Persson, P. O. G.: 2004, ‘Measurements of the von Kármán Constant in the Atmospheric Surface Layer – Further Discussions’, in 16th Conference on Boundary Layers and Turbulence, Portland ME, Amer. Meteorol. Soc., paper 7.2, pp. 1–7.
Barrett E.W. and Suomi V.E. (1949). ‘Preliminary Report on Temperature Measurement by Sonic Means’. J. Meteorol. 6: 273–276
Bernhardt K.-H. (1995). ‘Zur Interpretation der Monin–Obuchovschen Länge’. Meteorol. Z. 4:81–82
Bovscheverov V.M. and Voronov V.P. (1960). ‘Akustitscheskii fljuger (Acoustic rotor)’. Izv. AN SSSR, ser. Geofiz. 6: 882–885
Bradley E.F. (1968). ‘A Shearing Stress Meter for Micrometeorological Studies’. Quart. J. Roy. Meteorol. Soc. 94:380–387
Businger J.A., Miyake M., Inoue E., Mitsuta Y., and Hanafusa T. (1969). ‘Sonic Anemometer Comparison and Measurements in the Atmospheric Surface Layer’. J. Meteorol. Soc. Japan 47:1–12
Businger J.A., Wyngaard J.C., Izumi Y., and Bradley E.F. (1971). ‘Flux–profile Relationships in the Atmospheric Surface Layer’. J. Atmos. Sci. 28:181–189
Businger J.A. and Yaglom A.M. (1971). ‘Introduction to Obukhov’s Paper “Turbulence in an Atmosphere with a Non-Uniform Temperature” ’. Boundary-Layer Meteorol. 2:3–6
Businger J.A. (1988). ‘A Note on the Businger–Dyer Profiles’. Boundary-Layer Meteorol. 42:145–151
Culf A.D., Foken T., and Gash J.H.C. (2004). ‘The Energy Balance Closure Problem’. In: Kabat P., Claussen M. et al. (eds). Vegetation, Water, Humans and the Climate A New Perspective on an Interactive System. Springer, Berlin, Heidelberg, pp. 159–166
Denmead D.T. and Bradley E.F. (1985). ‘Flux–Gradient Relationships in a Forest Canopy’. In: Hutchison B.A., Hicks B.B.(eds). The Forest-Atmosphere Interaction. D. Reidel Publ. Comp., Dordrecht, Boston, London, pp. 421–442
Dyer A.J., Hicks B.B., and King K.M. (1967). ‘The Fluxatron – A Revised Approach to the Measurement of Eddy Fluxes in the Lower Atmosphere’. J. Appl. Meteorol. 6:408–413
Dyer A.J. and Hicks B.B. (1970). ‘Flux–Gradient Relationships in the Constant Flux Layer’. Quart. J. Roy. Meteorol. Soc. 96:715–721
Dyer A.J. (1974). ‘A Review of Flux-Profile-Relationships’. Boundary-Layer Meteorol. 7:363–372
Dyer A.J., Garratt J.R., Francey R.J., McIlroy I.C., Bacon N.E., Hyson P., Bradley E.F., Denmead D.T., Tsvang L.R., Volkov J.A., Kaprov B.M., Elagina L.G., Sahashi K., Monji N., Hanafusa T., Tsukamoto O., Frenzen P., Hicks B.B., Wesely M., Miyake M., and Shaw W.J. (1982). ‘An International Turbulence Comparison Experiment (ITCE 1976)’. Boundary-Layer Meteorol. 24:181–209
Foken T., Kitajgorodskij S.A., and Kuznecov O.A. (1978). ‘On the Dynamics of the Molecular Temperature Boundary Layer above the Sea’. Boundary-Layer Meteorol. 15:289–300
Foken T. and Kuznecov O.A. (1978). ‘Die wichtigsten Ergebnisse der gemeinsamen Expedition “KASPEX-76” des Institutes für Ozeanologie Moskau und der Karl-Marx-Universität Leipzig’. Beitr. Meeresforsch. 41:41–47
Foken T. and Skeib G. (1983). ‘Profile Measurements in the Atmospheric Near-Surface Layer and the Use of Suitable Universal Functions for the Determination of the Turbulent Energy Exchange’. Boundary-Layer Meteorol. 25:55–62
Foken T. (1990). ‘Turbulenter Energieaustausch zwischen Atmosphäre und Unterlage – Methoden, meßtechnische Realisierung sowie ihre Grenzen und Anwendungsmöglichkeiten’. Ber. Dt. Wetterdienstes 180:287
Foken T. and Bernhardt K. (1994). ‘Atmospheric Boundary Layer Research in Central and East European Countries with KAPG, 1981–1990’. Geophys. Rep. 01:1–58
Foken T. and Oncley S.P. (1995). ‘Results of the Workshop “Instrumental and Methodical Problems of Land Surface Flux Measurements”’. Bull. Amer. Meteorol. Soc. 76:1191–1193
Foken T. (2003). Angewandte Meteorologie, Mikrometeorologische Methoden. Springer, Heidelberg, 289 pp.
Garratt J.R. (1980). ‘Surface Influence upon Vertical Profiles in the Atmospheric Near Surface Layer’. Quart. J. Roy. Meteorol. Soc. 106:803–819
Garratt J.R. and Hicks B.B. (1990). ‘Micrometeorological and PBL Experiments in Australia’. Boundary-Layer Meteorol. 50:11–32
Garratt J.R. (1992). The Atmospheric Boundary Layer. Cambridge University Press, Cambridge, 316 pp.
Geiger R. (1927). Das Klima der bodennahen Luftschicht. Friedr. Vieweg & Sohn, Braunschweig, 246 pp.
Geiger R., Aron R.H., and Todhunter P. (1995). The Climate Near the Ground. Friedr. Vieweg & Sohn Verlagsges. mbH, Braunschweig, Wiesbaden, 528 pp.
Hanafusa T., Fujitana T., Kobori Y., and Mitsuta Y. (1982). ‘A New Type Sonic Anemometer–Thermometer for Field Operation’. Papers in Meteorol. & Geophys. 33:1–19
Handorf D., Foken T., and Kottmeier C. (1999). ‘The Stable Atmospheric Boundary Layer over an Antarctic Ice Sheet’. Boundary-Layer Meteorol. 91:165–186
Haugen D.H. (eds) (1973). ‘Workshop on Micrometeorology’. Amer. Meteorol. Soc., Boston, 392 pp.
Hess G.D., Hicks B.B., and Yamada T. (1981). ‘The Impact of the Wangara Experiment’. Boundary-Layer Meteorol. 20: 135–174
Hicks B.B. (1986). ‘Book Review: ‘“International Turbulence Comparison Experiment ITCE 1981”’. Boundary-Layer Meteorol. 34:417–419
Högström U. (1974). ‘A Field Study of the Turbulent Fluxes of Heat Water Vapour and Momentum at a ‘Typical’ Agricultural Site’. Quart. J. Roy. Meteorol. Soc. 100:624–639
Högström U. (1985). ‘Von Kármán Constant in Atmospheric Boundary Flow: Reevaluated’. J. Atmos. Sci. 42: 263–270
Högström U. (1988). ‘Non-dimensional Wind and Temperature Profiles in the Atmospheric Surface Layer: A Re-evaluation’. Boundary-Layer Meteorol. 42:55–78
Högström U. (1990). ‘Analysis of Turbulence Structure in the Surface Layer with a Modified Similarity Formulation for Near Neutral Conditions’. J. Atmos. Sci. 47:1949–1972
Högström U. (1996). ‘Review of Some Basic Characteristics of the Atmospheric Surface Layer’. Boundary-Layer Meteorol. 78:215–246
Högström U. and Bergstrom H. (1996). ‘Organized Turbulence Structures in the Near-Neutral Atmospheric Surface Layer’. J. Atmos. Sci. 53:2452–2464
Izumi, Y.: (1971), Kansas 1968 Field Program Data Report. Bedford, MA, Air Force Cambridge Research Papers, No. 379, 79 pp.
Johansson C., Smedman A., Högström U., Brasseur J.G., and Khanna S. (2001). ‘Critical Test of Monin–Obukhov Similarity During Convective Conditions’. J. Atmos. Sci. 58:1549–1566
Kader B.A. and Yaglom A.M. (1972). ‘Heat and Mass Transfer Laws for Fully Turbulent Wall Flows’. Int. J. Heat Mass Transfer 15:2329–2350
Kader B.A. and Yaglom A.M. (1990). ‘Mean Fields and Fluctuation Moments in Unstably Stratified Turbulent Boundary Layers’. J. Fluid Mech. 212:637–662
Kaimal J.C. and Businger J.A. (1963). ‘A Continuous Wave Sonic Anemometer–Thermometer’. J. Climate Appl. Meteorol. 2:156–164
Kaimal J.C. and Wyngaard J.C. (1990). ‘The Kansas and Minnesota Experiments’. Boundary-Layer Meteorol. 50:31–47
Kantha L.H. and Clayson C.A. (2000). Small Scale Processes in Geophysical Fluid Flows. Academic Press, San Diego, 883 pp.
von Kármán T. and Howarth L. (1938). ‘On the Statistical Theory of Isotropic Turbulence’. Proc. Roy. Soc. London A 164:192–215
Kleinschmidt E. (eds) (1935). Handbuch der meteorologischen Instrumente und ihrer Auswertung. Springer, Berlin, 733 pp.
Kolmogorov A.N. (1941a). ‘Lokalnaja struktura turbulentnosti v neschtschimaemoi schidkosti pri otschen bolschich tschislach Reynoldsa (The Local Structure of Turbulence in Incompressible Viscous Fluid for Very Large Reynolds Numbers)’. Dokl. AN SSSR 30:299–303
Kolmogorov A.N. (1941b). ‘Rassejanie energii pri lokolno-isotropoi turbulentnosti (Dissipation of Energy in Locally Isotropic Turbulence)’. Dokl. AN SSSR 32:22–24
Kondo J. and Sato T. (1982). ‘The Determination of the von Kármán Constant’. J. Meteorol. Soc. Japan 60:461–471
Lee X., Massman W.J. and Law B. (eds) (2004). Handbook of Micrometeorology: A Guide for Surface Flux Measurement and Analysis. Kluwer, Dordrecht, 250 pp.
Lettau H. (1939). Atmosphärische Turbulenz. Akad. Verlagsges., Leipzig, 283 pp.
Lettau H. (1949). ‘Isotropic and Non-Isotropic Turbulence in the Atmospheric Surface Layer’. Geophys. Res. Pap. 1:86
Lettau H.H. (eds) (1957). Exploring the Atmosphere’s First Mile, Vol1. Pergamon Press, London, New York, 376 pp.
Lumley J.L. and Yaglom A.M. (2001). ‘A Century of Turbulence’. Flow Turbulence Combust. 66:241–286
McBean G.A., Bernhardt K., Bodin S., Litynska Z., van Ulden A.P., and Wyngaard J.C. (1979). ‘The Planetary Boundary Layer’. WMO, Note 530:201
Mitsuta Y. (1966). ‘Sonic Anemometer-Thermometer for General Use’. J. Meteorol. Soc. Japan Ser. II 44:12–24
Miyake M., Stewart R.W., Burling R.W., Tsvang L.R., Kaprov B.M., and Kuznecov O.A. (1971). ‘Comparison of Acoustic Instruments in an Atmospheric Flow Over Water’. Boundary-Layer Meteorol. 2:228–245
Monin A.S. and Obukhov A.M. (1954). ‘Osnovnye zakonomernosti turbulentnogo peremeshivanija v prizemnom sloe atmosfery (Basic Laws of Turbulent Mixing in the Atmosphere Near the Ground)’. Trudy geofiz. inst. AN SSSR 24(151): 163–187
Monin A.S. and Yaglom A.M. (1973). Statistical Fluid Mechanics: Mechanics of Turbulence, Vol 1. MIT Press, Cambridge, London, 769 pp.
Monin A.S. and Yaglom A.M. (1975). Statistical Fluid Mechanics: Mechanics of Turbulence, Vol 2. MIT Press, Cambridge, London, 874 pp.
Montgomery R.B. (1948). ‘Vertical Eddy Flux of Heat in the Atmosphere’. J. Meteorol. 5:265–274
Obukhov A.M. (1946). ‘Turbulentnost’ v temperaturnoj–neodnorodnoj atmosfere (Turbulence in an Atmosphere with a Non-uniform Temperature)’. Trudy Inst. Theor. Geofiz. AN SSSR 1:95–115
Obukhov A.M. (1951). ‘Charakteristiki mikrostruktury vetra v prizemnom sloje atmosfery (Characteristics of the Micro-structure of the Wind in the Surface Layer of the Atmosphere)’. Izv. AN SSSR, ser. Geofiz. 3:49–68
Obukhov A.M. (1960). ‘O strukture temperaturnogo polja i polja skorostej v uslovijach konvekcii (Structure of the Temperature and Velocity Fields Under Conditions of Free Convection)’. Izv. AN SSSR, ser. Geofiz. 9:1392–1396
Obukhov A.M. (1971). ‘Turbulence in an Atmosphere with a Non-uniform Temperature’. Boundary-Layer Meteorol. 2:7–29
Oncley S.P., Friehe C.A., Larue J.C., Businger J.A., Itsweire E.C., and Chang S.S. (1996). ‘Surface-layer Fluxes, Profiles, and Turbulence Measurements over Uniform Terrain Under Near-neutral Conditions’. J. Atmos. Sci. 53:1029–1054
Paeschke W. (1937). ‘Experimentelle Untersuchungen zum Rauhigkeitsproblem in der bodennahen Luftschicht’. Z. Geophys. 13:14–21
Panin G.N., Tscherevitinov F.O., and Piacena C. (1982). ‘O vlijanii stratifikacii vozducha na processy vzaimodejsvija vodoema s atmosfery (About the Influence of the Stability on Air–Sea Interaction)’. Acta Hydrophys. 27:229–244
Panofsky H.A. (1963). ‘Determination of Stress from Wind and Temperature Measurements’. Quart. J. Roy. Meteorol. Soc. 89: 85–94
Prandtl L. (1925). ‘Bericht über Untersuchungen zur ausgebildeten Turbulenz’. Z. angew. Math. Mech. 5:136–139
Priestley C.H.B. and Swinbank W.C. (1947). ‘Vertical Transport of Heat by Turbulence in the Atmosphere’. Proc. Roy. Soc. London A 189:543–561
Pruitt W.O., Morgan D.L., and Lourence F.J. (1973). ‘Momentum and Mass Transfer in the Surface Boundary Layer’. Quart. J. Roy. Meteorol. Soc. 99:370–386
Raupach M.R., Thom A.S., and Edwards I. (1980). ‘A Wind-Tunnel Study of Turbulent Flow Close to Regularly Arrayed Rough Surface’. Boundary-Layer Meteorol. 18:373–379
Raupach M.R., Finnigan J.J., and Brunet Y. (1996). ‘Coherent Eddies and Turbulence in Vegetation Canopies: The Mixing-layer Analogy’. Boundary-Layer Meteorol. 78:351–382
Reynolds O. (1894). ‘On the Dynamical Theory of Turbulent Incompressible Viscous Fluids and the Determination of the Criterion’. Phil. Trans. R. Soc. London A 186:123–161
Richardson L.F. (1920). ‘The Supply of Energy from and to Atmospheric Eddies’. Proc. Roy. Soc. A 97:354–373
Schmidt W. (1925). Der Massenaustausch in freier Luft und verwandte Erscheinungen. Henri Grand Verlag, Hamburg, 118 pp.
Schotland R.M. (1955). ‘The Measurement of Wind Velocity by Sonic Waves’. J. Meteorol. 12:386–390
Sheppard P.A. (1947). ‘The Aerodynamic Drag of the Earth’s Surface and the Value of von Karman’s Constant in the Lower Atmosphere’. Proc. Roy. Soc. A 188:208
Stull R.B. (1988). An Introduction to Boundary Layer Meteorology. Kluwer Academic Publishers, Dordrecht, 666 pp.
Suomi V.E. (1957). ‘Sonic Anemometer – University of Wisconsin’. In: Lettau H.H. and Davidson B. (eds). Exploring the Atmosphere’s First Mile. Pergamon Press, London, New York, pp. 256–266
Swinbank W.C. (1951). ‘The Measurement of Vertical Transfer of Heat and Water Vapor by Eddies in the Lower Atmosphere’. J. Meteorol. 8:135–145
Swinbank W.C. (1964). ‘The Exponential Wind Profile’. Quart. J. Roy. Meteorol. Soc. 90:119–135
Swinbank W.C. (1968). ‘A Comparison between Prediction of the Dimensional Analysis for the Constant-Flux Layer and Observations in Unstable Conditions’. Quart. J. Roy. Meteorol. Soc. 94:460–467
Swinbank W.C. and Dyer A.J. (1968). ‘An Experimental Study on Mircrometeorology’. Quart. J. Roy. Meteorol. Soc. 93: 494–500
Taylor G.I. (1915). ‘Eddy Motion in the Atmosphere’. Phil. Trans. Roy. Soc. London A 215:1–26
Taylor G.I. (1938). ‘The Spectrum of Turbulence’. Proc. Roy. Soc. London A 164:476–490
Tschalikov D.V. (1968). ‘O profilja vetra i temperatury v prizemnom sloe atmosfery pri ustojtschivoj stratifikacii (About the Wind and Temperature Profile in the Surface Layer for Stable Stratification)’. Trudy GGO 207:170–173
Tsvang L.R., Kaprov B.M., Zubkovskij S.L., Dyer A.J., Hicks B.B., Miyake M., Stewart R.W., and McDonald J.W. (1973). ‘Comparison of Turbulence Measurements by Different Instuments; Tsimlyansk Field Experiment 1970’. Boundary-Layer Meteorol. 3:499–521
Tsvang L.R., Zubkovskij S.L., Kader B.A., Kallistratova M.A., Foken T., Gerstmann W., Przandka Z., Pretel J., Zelený J., and Keder J. (1985). ‘International Turbulence Comparison Experiment (ITCE-81)’. Boundary-Layer Meteorol. 31:325–348
Webb E.K. (1970). ‘Profile Relationships: The Log-Linear Range, and Extension to Strong Stability’. Quart. J. Roy. Meteorol. Soc. 96:67–90
Wieringa J. (1980). ‘A Revaluation of the Kansas Mast Influence on Measurements of Stress and Cup Anemometer Overspeeding’. Boundary-Layer Meteorol. 18:411–430
Wyngaard J.C., Businger J.A., Kaimal J.C., and Larsen S.E. (1982). ‘Comments on “A Revaluation of the Kansas Mast Influence on Measurements of Stress and Cup Anemometer Overspeeding”’. Boundary-Layer Meteorol. 22:245–250
Yaglom A.M. (1977). ‘Comments on Wind and Temperature Flux-Profile Relationships’. Boundary-Layer Meteorol. 11: 89–102
Yaglom A.M. (1990). ‘Alexander Mikhailovich Obukhov, 1918–1989’. Boundary-Layer Meteorol. 53:v–xi
Zilitinkevich S.S. and Tschalikov D.V. (1968). ‘Opredelenie universalnych profilej skorosti vetra i temperatury v prizemnom sloe atmosfery (Determination of Universal Profiles of Wind Velocity and Temperature in the Surface Layer of the Atmosphere)’. Izv. AN SSSR, Fiz. Atm. i Okeana 4:294–302
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Foken, T. 50 Years of the Monin–Obukhov Similarity Theory. Boundary-Layer Meteorol 119, 431–447 (2006). https://doi.org/10.1007/s10546-006-9048-6
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DOI: https://doi.org/10.1007/s10546-006-9048-6