LIST
OF PUBLICATIONS
1.
Arms, S., P. Klein, and
2.
Borisov I.
A., O. I. Soboleva, E. D. Suglobova, and E. E. Fedorovich, 1994: Na+ and K+ ion
transport across the human erythrocyte membrane during the formation of
nystatin channels under in-vitro conditions: the characteristics and analysis
of the processes. Tsitologia, 36, 427-436, in Russ.
1.
Botnick, A. M., and
2.
Burkholder, B., A. Shapiro, and E. Fedorovich, 2008: Two-dimensional katabatic flows along a planar slope. Abstr. 18th AMS Symposium on Boundary Layers and
Turbulence, June 9-13, 2008,
3.
Burkholder, B., A. Shapiro, and E. Fedorovich, 2009: Katabatic flow induced by a cross-slope band of surface cooling. Acta Geophysica, 57,
923-949. AG
2009 Burkholder et al.pdf
4.
Conzemius,
R., and E. Fedorovich, 2001: Entrainment dynamics of shear-free convective
boundary layers growing in linearly and discretely stratified fluids. Proc.
Third Intern. Symp. on Environmental Hydraulics, 5-8 December 2001,
5.
Conzemius,
R., and E. Fedorovich, 2002: Dynamics of convective entrainment in a
heterogeneously stratified atmosphere with wind shear. Proc. 15th AMS Symp. on
Boundary Layers and Turbulence, 15-19 July 2002, Wageningen, The
6.
Conzemius,
R., and E. Fedorovich, 2003a: Evolution of mean wind and turbulence fields in a quasi-baroclinic
convective boundary layer with strong wind shears. Proc.
11th Intern. Conf. on Wind
7.
Conzemius
R. J., and E. Fedorovich, 2003b: Wind shear enhancement
of convective boundary layer growth. Abstr. 2003 IUGG General Assembly, June 30 - July 11, 2003,
8.
Conzemius
R., and E. Fedorovich, 2004a: Predictions of entrainment into a sheared
atmospheric convective boundary layer by large eddy simulation versus
two-parameter turbulence closure model. Geophysical Research Abstracts, 6, 05343, 2004.
9.
Conzemius, R., and E.
Fedorovich, 2004b: Numerical models of entrainment into sheared convective
boundary layers evaluated through large eddy simulations. Preprints, 16th Symp.
on Boundary Layers and Turbulence, Amer. Meteor. Soc., 9-13
August,
10.
Conzemius
R., and E. Fedorovich, 2005: Essential features of entrainment in the sheared
atmospheric convective boundary layer as represented by first- and second-order
bulk models. Geophysical
Research Abstracts, 7, 10265,
2005.
11.
Conzemius,
R. J., and
12.
Conzemius,
R. J., and
13.
Conzemius, R., and E.
Fedorovich, 2007: Bulk
models of the sheared convective boundary layer: evaluation through large eddy
simulations. J. Atmos. Sci., 64, 786-807. JAS
2007 Conzemius & Fedorovich.pdf
14.
Conzemius, R., and E. Fedorovich, 2008a: Simulations versus observations of a sheared convective boundary
layer. Abstr. Inaugural International Conference of the
Engineering Mechanics Institute (EM08), May 18-21,
2008, University of Minnesota, Minneapolis, USA, p. 216.
15.
Conzemius, R. J., and
16.
Conzemius, R., and E. Fedorovich, 2008b: Simulations versus observations of a sheared convective boundary
layer. Abstr. 18th AMS Symposium on Boundary
Layers and Turbulence, June
9-13, 2008,
17.
Di
Sabatino, S., P. Kastner-Klein, R. Berkowicz, R. Britter, and E. Fedorovich,
2003: The modelling of turbulence from traffic in urban dispersion models
– Part I: Theoretical considerations. Environmental
Fluid Mechanics, 3, 129-143. EFM
2003 Part I Di Sabatino et al.pdf
18.
Dubov, A.
S., and E. E. Fedorovich, 1986: Numerical method for calculation of the
atmospheric boundary layer over two-dimensional obstructions of moderate slope.
Abstr. Fourth Int. Conf. on Boundary and
Interior Layers,
19.
Dyubkin,
I. A., and E. E. Fedorovich, 1982: Estimation of the influence of random
measurement errors on the statistical characteristics of meteorological time
series. Trudy GGO, 447, 115-123, in Russ.
20.
Dyubkin,
I. A., R. G. Timanovskaya, and E. E. Fedorovich, 1983: In-station control of
the heat balance components measured aboard the research ships with the aid of
automated and semi-automated measuring technique. Trudy GOIN, 163, in
Russ.
21.
Fedorovich,
E. E., 1984: Some properties of the double parameter solutions of the boundary
layer model equations for the equilibrium conditions. Trudy GGO, 483, in Russ.
22.
Fedorovich,
E. E., 1985a: A numerical model of flow over by air stream of extended relief
forms. Meteorologiya i Gidrologiya, n7, 34-40, in Russ. Engl. translation in
Meteorology and Hydrology, Wash., D.C. Available from NTIS, Springfield,
VA 22161, MGA (1986), 37:6-170.
23.
Fedorovich,
E. E., 1985b: A numerical model of the stratified atmospheric boundary layer
over extended relief forms. Abstr.
All-Union Meeting on Mountain Meteorology,
24.
Fedorovich,
E. E., 1986a: Variational approach towards calculation of the turbulent
exchange coefficient in the atmospheric boundary layer on the basis of wind
measurement data. Trudy GGO, 502, in Russ.
25.
Fedorovich,
E. E., 1986b: On the solution of the atmospheric boundary layer equations for
stream function and vorticity. Trudy GGO,
504, in Russ.
26.
Fedorovich,
E. E., 1990: Comparative analysis of the algorithms for the surface fluxes
evaluation on the basis of standard meteorological data. Proc. 5th
27.
Fedorovich,
E. E., 1991a: Numerical modelling of the slope effects in the atmospheric
boundary layer. Meteorologiya i
Gidrologiya, n8, 56-65, in Russ.
Engl. translation in Meteorology and Hydrology, Wash., D.C. Available
from NTIS, Springfield, VA 22161, MGA (1992), 43:8-383.
28.
Fedorovich,
E. E., 1991b: Numerical modelling of the atmospheric boundary-layer flow over
ridge- and valley-type artificial obstacles. Abstr. EUROMECH 276 Colloquium on the Dynamics of the Urban Atmosphere,
29.
Fedorovich,
E. E., 1992: A parameterized model of the entrainment at the top of the
atmospheric convectively mixed layer. Abstr.
XVII General Assembly of the European Geophysical Society, Annales Geophysicae,
Supplement to Volume 10, Part II, C272.
30.
Fedorovich,
E., 1995a: Modeling the atmospheric convective boundary layer within a
zero-order jump approach: an extended theoretical framework. J. Appl. Meteor., 34, 1916-1928. JAM
1995 Fedorovich.pdf
31.
Fedorovich,
E. E., 1995b: Inversion layers. Diffusion
and Transport of Pollutants in the Atmospheric Mesoscale Flow Fields, A.
Gyr and F.-S. Rys, Eds., Kluwer, 191-211. Diffusion
and Transport 1995 Fedorovich.pdf
32.
Fedorovich,
E., 1998: Bulk models of the atmospheric convective boundary layer. Buoyant Convection in Geophysical Flows,
E. J. Plate et al., Eds., Kluwer, 265-290. Buoyant
Convection 1998 Fedorovich.pdf
33.
Fedorovich,
E. E., 1999: Review of “Buoyant
Convection in Geophysical Flows”, NATO Scientific Publications
Newsletter, 69, p. 2.
34.
Fedorovich, E., 2004a:
Dispersion of passive tracer in the atmospheric convective boundary layer with
wind shears: a review of laboratory and numerical model studies. Meteorol. Atmos. Phys., 87, 3-21. MAP2004
Fedorovich.pdf
35.
Fedorovich, E., 2004b:
Dispersion in atmospheric convective boundary layer with wind shears: from
laboratory models to complex simulation studies. Preprints, 5th Symp.
on the Urban Environment, Amer. Meteor. Soc., 23-26 August,
36.
Fedorovich, E., 2008:
Flux-profile calculations in the atmospheric surface layer based on multi-level
measurement data. Tutorial Manual of
International Summer School on Atmospheric Boundary Layers,
37.
Fedorovich,
E. E., and E. N. Churina, 1988: Application of the spline-approximation methods
on the chaotic grid to the problems of smoothing and interpolation of
near-surface meteorological fields. Abstr.
All-Union Conf.,
38.
Fedorovich,
E. E., and E. N. Churina, 1989: Development of a fast algorithm for the problem
of local wind field adaptation accounting for conservation laws. Abstr. Summer School,
39.
Fedorovich,
E., and R. Conzemius, 2001: Large-eddy simulation of convective entrainment in
linearly and discretely stratified fluids. Direct and Large-Eddy Simulation
IV, B. J. Geurts et al., Eds., Kluwer, 435-442. DNS
and LES 2001 Fedorovich & Conzemius.pdf
40.
Fedorovich,
E., and R. Conzemius, 2002a: Evolution of turbulent convective entrainment in
heterogeneously versus linearly stratified fluids. Advances in Turbulence IX,
I. Castro et al., Eds., CIMNE Publication,
41.
Fedorovich,
E., and R. Conzemius, 2002b: Effects of initial temperature and velocity
perturbations on the development of convection in the atmospheric boundary
layer. Proc. 15th AMS Symp. on Boundary Layers and Turbulence,
15-19 July 2002, Wageningen, The
42.
Fedorovich,
E., and R. Conzemius, 2004: Numerical evaluation of wind-shear effects on
turbulence regime and entrainment dynamics in the atmospheric convective
boundary layer. Geophysical
Research Abstracts, 6, 05370,
2004.
43.
Fedorovich
E., and R. Conzemius, 2005: Velocity scales associated with different
entrainment-contributing mechanisms in the sheared atmospheric convective
boundary layer. Geophysical
Research Abstracts, 7, 09821,
2005.
44.
Fedorovich, E., and R. Conzemius, 2008a: Effects of
wind shear on the atmospheric convective boundary layer structure and
evolution. Acta Geophysica, 56,
114-141. AG
2008 Fedorovich & Conzemius.pdf
45.
Fedorovich, E., and R. Conzemius, 2008b: Numerical simulation and
parameterization of entrainment into sheared convective boundary layers. Abstr. Inaugural International Conference of the
Engineering Mechanics Institute (EM08), May 18-21,
2008, University of Minnesota, Minneapolis, USA, p. 242.
46.
Fedorovich, E., R. Conzemius,
47.
Fedorovich, E., R. Conzemius,
and D. Mironov, 2004b: Convective entrainment into a
shear-free linearly stratified atmosphere: bulk models re-evaluated through
large eddy simulations. J. Atmos. Sci., 61, 281-295. JAS
2004 Fedorovich et al.pdf
48.
Fedorovich, E., R. Conzemius,
and A. Shapiro, 2004c: Nonstationarity of convective boundary layer growth in a
heterogeneously stratified, shear-free atmosphere. Preprints, 16th Symp.
On Boundary Layers and Turbulence, Amer. Meteor. Soc., 9-13
August,
49.
Fedorovich,
E., G. H. Jirka, E. J. Plate, and R. Kolotilo, 1998: Investigation and
parameterization of scale interactions in the convective boundary-layer flow
turbulence using unified atmospheric, wind-tunnel, and numerical model database. Zwischenbericht. Institut für Hydromechanik (IfH),
Universität Karlsruhe, Bericht Nr. 753,
76 pp., (available from IfH, Universität Karlsruhe, Kaiserstraße 12,
76128 Karlsruhe, Germany).
50.
Fedorovich,
E., G. H. Jirka, J. Thäter, and E. J. Plate, 2002: Investigation and
parameterization of scale interactions in the convective boundary-layer flow
turbulence using unified atmospheric, wind-tunnel, and numerical model database. Endbericht. Institut für Hydromechanik (IfH),
Universität Karlsruhe, Bericht Nr. 792,
54 pp., (available from IfH, Universität Karlsruhe, Kaiserstraße 12,
76128 Karlsruhe, Germany).
51.
Fedorovich,
E., and R. Kaiser, 1997a: Statistical structure of turbulence in a wind tunnel model
of the atmospheric convective boundary layer. Abstr. Colloquium on Clear and Cloudy Boundary Layers, 26-29 August
1997, Royal Netherlands Academy of Arts and Sciences, Amsterdam, The
Netherlands.
52.
Fedorovich,
E., and R. Kaiser, 1997b: A model study of mixing and entrainment in the
horizontally evolving atmospheric convective boundary layer. Proc. EURASAP Workshop on Determination of
the Mixing Height, 1-3 October 1997, Risø National Laboratory,
Roskilde, Denmark, 17-20.
53.
Fedorovich,
E., and R. Kaiser, 1998a: Wind tunnel model study of turbulence regime in the
atmospheric convective boundary layer. Buoyant
Convection in Geophysical Flows, E. J. Plate et al., Eds., Kluwer, 327-370.
Buoyant
Convection 1998 Fedorovich & Kaiser.pdf
54.
Fedorovich,
E., and R. Kaiser, 1998b: Turbulent mixing and entrainment in a horizontally
evolving convective boundary layer capped by a temperature inversion. Abstr. Symp. on Developments in Geophysical
Turbulence. 16-19 June 1998,
55.
Fedorovich,
E., and R. Kaiser, 1998c: Investigation of turbulence structure in the
convective boundary layer by means of LDA measurements and large-eddy numerical
simulation. Abstr. Workshop on Flow
Diagnosis Techniques. 30 June – 3 July 1998, State Marine Technology
University,
56.
Fedorovich,
E., R. Kaiser, and M. Rau, 1995a: Convective boundary layer turbulence spectra
and dissipation rates derived from wind-tunnel simulations. Abstr. Workshop on Interaction of Scales in
Turbulence, 13-15 March 1995,
57.
Fedorovich,
E., R. Kaiser, and M. Rau, 1995b: Simulation of convective boundary layer
turbulence structure in the thermally stratified wind tunnel. Proc. 11th AMS Symposium on Boundary Layer
and Turbulence, 27-31 March 1995, Charlotte, North Carolina, USA, 544-547.
58.
Fedorovich,
E., R. Kaiser, and M. Rau, 1995c: Wind-tunnel study of turbulence regime in the
convective boundary layer with shear. Proc.
10th Symposium on Turbulent Shear Flows, 14-16 August 1995,
59.
Fedorovich,
E., R. Kaiser, M. Rau, and E. Plate, 1996: Wind tunnel study of turbulent flow
structure in the convective boundary layer capped by a temperature inversion. J. Atmos. Sci., 53, 1273-1289. JAS
1996 Fedorovich et al.pdf
60.
Fedorovich,
E. E., and A. E. Kirimov, 1988: Double-parameter description of turbulence in
the models of the stratified boundary layer over the inclined surface. Abstr. Int. Symp. on the Atmospheric
Boundary Layer in the Urban Conditions,
61.
Fedorovich,
E. E., and A. E. Kirimov, 1989: Modelling atmospheric boundary layer along
inclined surface in the framework of the b-e closure scheme for hydro- and thermodynamics
equations. Abstr. Summer School,
62.
Fedorovich,
E. E., and A. E. Kirimov, 1991: Two-parameter turbulence closure schemes in the
slope wind modelling. Proc. 8th Symp. on
Turbulent Shear Flows,
63.
Fedorovich,
E. E., and D. V. Mironov, 1995: A model for shear-free convective boundary
layer with parameterized capping inversion structure. J. Atmos. Sci., 52,
83-95. JAS
1995 Fedorovich & Mironov.pdf
64.
Fedorovich,
E., F. T. M. Nieuwstadt, and R. Kaiser, 2001a: Numerical and laboratory study
of horizontally evolving convective boundary layer. Part I: Transition regimes
and development of the mixed layer. J.
Atmos. Sci., 58, 70-86. JAS
2001 Fedorovich et al Part I.pdf
65.
Fedorovich,
E., F. T. M. Nieuwstadt, and R. Kaiser, 2001b: Numerical and laboratory study
of horizontally evolving convective boundary layer. Part II: Effects of elevated
wind shear and surface roughness. J.
Atmos. Sci., 58, 546-560. JAS
2001 Fedorovich et al Part II.pdf
66.
Fedorovich, E., R. Rotunno, and
B. Stevens, Eds. 2004d: Atmospheric
Turbulence and Mesoscale Meteorology.
67.
Fedorovich, E., and A. Shapiro,
2006a: Oscillatory flow regimes in turbulent katabatic flows retrieved from
direct numerical simulations. Abstr. 17th AMS Symposium on Boundary Layers
and Turbulence, American
Meteorological Society, May 22-25, 2006, San Diego, USA, J6.13.
68.
Fedorovich, E., and A. Shapiro,
2006b: Effects of rotation and turbulence-wave interactions in numerically
simulated katabatic flows. Abstr. International
Workshop on Stable Boundary Layers, Arizona State
University and Army Research Office, November 13-16, 2006, Sedona, USA, 25.
69.
Fedorovich, E., and A. Shapiro, 2008: Scaling relationships
for slope flows. Abstr. 18th AMS Symposium on Boundary
Layers and Turbulence, June
9-13, 2008,
70.
Fedorovich, E., and A. Shapiro, 2009a: Turbulence and waves
in numerically simulated slope flows. Mécanique & Industries, 10, 175-179. MI
2009 Fedorovich & Shapiro.pdf
71.
Fedorovich, E., and A. Shapiro, 2009b: Structure of
numerically simulated katabatic and anabatic flows along steep slopes. Acta Geophysica, 57, 981-1010. AG
2009 Fedorovich & Shapiro.pdf
72.
Fedorovich, E., and A. Shapiro, 2009c: Turbulent
natural convection along a vertical plate immersed in a stably stratified fluid. J.
Fluid Mech., 636,
41-57. JFM
2009 Fedorovich & Shapiro.pdf
73.
Fedorovich,
E., and J. Thäter, 2000: Turbulent transport across a sheared inversion at
the convective boundary layer top. Advances in Turbulence VIII, C.
Dopazo et al., Eds., CIMNE Publication,
74.
Fedorovich, E., and J.
Thäter, 2001: Vertical transport
of heat and momentum across a sheared density interface at the top of a horizontally
evolving convective boundary layer. Journal
of Turbulence, 2, 007. JoT
2001 Fedorovich & Thaeter.pdf
75.
Fedorovich,
E., and J. Thäter, 2002: A wind tunnel study of gaseous tracer dispersion
in the convective boundary layer capped by a temperature inversion. Atmospheric Environment, 36,
2245-2255. AE
2002 Fedorovich & Thaeter.pdf
76.
Ilyin, B.
M., E. E. Fedorovich, and E. N. Churina, 1988: Algorithm for the calculation of
the climatic characteristics of the global radiation using routine
observational data. Meteorologiya i
Gidrologiya, n1, 118-123, in
Russ. Engl. translation in Meteorology and Hydrology, Wash., D.C.
Available from NTIS, Springfield, VA 22161, MGA (1990), 41:6-282.
77.
Ilyin, B.
M., E. E. Fedorovich, and E. N. Churina, 1989: Experience of splines
application for calculation of the climatic characteristics of the global
radiation using routine observational data. Trudy
GGO, 523, in Russ.
78.
Kaiser,
R., and E. Fedorovich, 1998: Turbulence spectra and dissipation rates in a wind
tunnel model of the atmospheric convective boundary layer. J. Atmos. Sci., 55, 580-594. JAS
1998 Kaiser & Fedorovich.pdf
79.
Kastner-Klein, P., R. Berkowicz, and E. Fedorovich, 2001: Evaluation of scaling
concepts for traffic-produced turbulence based on laboratory and full-scale
concentration measurements in street canyons. Abstr. 2nd Intern. Conf. on Urban
Air Quality, 19-23 March
2001,
80.
Kastner-Klein, P., S. Di Sabatino, M. Ketzel, A.
Kovar-Panskus, P. Louka, S. Trini Castelli, R. Berkowicz, R. Britter, E.
Fedorovich, and J.-F. Sini, 2002: The modeling of traffic produced turbulence. Optimisation of Modelling Methods for Traffic
Pollution in Streets, Final
Report of the EU TMR Project TRAPOS,
European Commission,
81.
Kastner-Klein,
P., and E. Fedorovich, 1999a: Diffusion from a line source deployed in a
homogeneous roughness layer: interpretation of wind-tunnel measurements by
means of simple mathematical models. Abstr.
EC391 EUROMECH Colloq. on Wind Tunnel Modelling of Dispersion in Environmental
Flows. 13-15 September,
82.
Kastner-Klein,
P., and E. Fedorovich, 1999b: Wind tunnel study of concentration and flow
fields near street canyon intersections. Abstr.
EC391 EUROMECH Colloq. on Wind Tunnel Modelling of Dispersion in Environmental
Flows. 13-15 September,
83.
Kastner-Klein,
P., and E. Fedorovich, 2002: Diffusion from a line source deployed in a
homogeneous roughness layer: interpretation of wind tunnel measurements by
means of simple mathematical models. Atmospheric
Environment, 36, 3709-3718. AE
2002 Kastner-Klein & Fedorovich.pdf
84.
Kastner-Klein,
P., E. Fedorovich, and R. Berkowicz, 1998: Application of LDA technique to flow
and turbulent diffusion diagnosis in a wind-tunnel model of urban street canyon
with moving vehicles. Abstr. Workshop on
Flow Diagnosis Techniques,
30 June – 3 July 1998,
85.
Kastner-Klein,
P., E. Fedorovich, M. S. Ketzel, R. Berkowicz, and R. Britter, 2003: The
modelling of turbulence from traffic in urban dispersion models – Part
II: Evaluation against laboratory and
full-scale concentration measurements in street canyons. Environmental Fluid Mechanics, 3, 145-172. EFM
2003 Part II Kastner-Klein et al.pdf
86.
Kastner-Klein,
P., E. Fedorovich, N. Kljun, and M. W. Rotach, 2001a: Dispersion of gaseous
plume in the sheared convective boundary layer: evaluation of a Lagrangian
particle model versus wind tunnel simulation data. Proc. Third Intern. Symp.
on Environmental Hydraulics, 5-8 December 2001,
87.
Kastner-Klein,
P., E. Fedorovich, and E. Plate, 1996: Wind-tunnel case studies of atmospheric
dispersion in the urban environment. Proc.
4th Workshop on Harmonisation within Atmospheric Dispersion Modelling for
Regulatory Purposes, 6-9 May 1996, Oostende, Belgium, 2, 435-442.
88.
Kastner-Klein,
P., E. Fedorovich, and E. Plate, 1997: Gaseous pollutant dispersion around
urban-canopy elements: wind tunnel case studies. Int. J. Environment and Pollution, 8, 727-737. IJEP
1997 Kastner-Klein et al.pdf
89.
Kastner-Klein,
P., E. Fedorovich, and M. W. Rotach, 1999a: Organised and turbulent air motions
in a wind tunnel model of a street canyon with and without moving vehicles. Abstr. Sixth Intern. Conf. on Harmonisation
within Atmospheric Dispersion Modelling, 11-14 October 1999,
90.
Kastner-Klein,
P., E. Fedorovich, and M. W.
Rotach, 2001b: A wind tunnel study of organized and turbulent air motions in
urban street canyons. J. Wind
91.
Kastner-Klein,
P., E. Fedorovich, J.-F. Sini, and P. G. Mestayer, 2000a: Experimental and
numerical verification of similarity concept for dispersion of car exhaust
gases in urban street canyons. Environmental
Monitoring and Assessment, 65,
353-361. EMA
2000 Kastner-Klein et al.pdf
92.
Kastner-Klein, P., M. Ketzel, S. Di
Sabatino, R. Berkowicz, R. Britter, and E. Fedorovich, 2002: Significance
of traffic produced turbulence for urban dispersion modeling. Proc. Fourth AMS Symp. on Urban Environment, 20-24 May 2002,
93.
Kastner-Klein,
P., J.-F. Sini, E. Fedorovich, and P. G. Mestayer, 1999: Similarity concept for
dispersion of car exhaust gases in street canyons tested against wind-tunnel
and numerical model data. Abstr. 2nd
Intern. Conf. on Urban Air Quality, 3-5 March 1999,
94.
Kastner-Klein,
P., M. W. Rotach, M. J. Brown, E. Fedorovich, and R. E. Lawson, 2000b: Spatial variability of mean flow and
turbulence fields in street canyons. Proc.
Third AMS Symp. on Urban Environment.
14-18 August 2000,
95.
Kastner-Klein,
P., M. W. Rotach, and E. Fedorovich, 2000c: Experimental study of mean flow and turbulence characteristics in an
urban roughness sublayer. Proc.
14th AMS Symp. on Boundary Layer and
Turbulence. 7-11 August 2000,
96.
Kljun N., P. Kastner-Klein, E. Fedorovich, and M. W. Rotach, 2004: Evaluation of Lagrangian footprint model using data from
wind tunnel convective boundary layer. Agric.
For. Meteorol., 127, 198-201. AFM
2004 Kljun et al.pdf
97.
Kljun, N.,
P. Kastner-Klein, M. W. Rotach, and E. Fedorovich, 2001: Evaluation of a 3D Lagrangian footprint model
with wind tunnel datasets for the convective boundary layer. Abstr. XXVI General Assembly of the European
Geophysical Society, Annales Geophysicae. March 26-30, 2001, Nice,
98.
Kljun N., P. Kastner-Klein, M. W.
Rotach, and E. Fedorovich, 2002: Evaluation
of the Lagrangian footprint model LPDM-B using wind-tunnel data sets. Proc. 15th AMS Symp. on Boundary Layers and Turbulence, 15-19 July 2002, Wageningen, The
99.
Lapshina,
Ye. G., Sokolova, G. P., and E. E. Fedorovich, 1992: Comparison of various
methods for the near-surface heat, moisture, and momentum fluxes evaluation on
the basis of the traditional meteorological observations. Trudy GGO, 539, 70-84, in Russ. English abstract in MGA (1993),
44:11-404.
100. Mironov, D., and E. Fedorovich, 2008: Effect of the Earth's rotation on the equilibrium depth of a stably
stratified barotropic planetary boundary layer. Abstr.
18th AMS Symposium on Boundary Layers and Turbulence, June 9-13, 2008,
101. Mordovina, L. S., and E. E. Fedorovich, 1989:
Comparison of the pressure reduction methods on use in the international
operational practice. Trudy GGO, 523, in Russ.
102. Plate, E. J., E. E. Fedorovich, D. X. Viegas,
and J. C. Wyngaard, Eds., 1998: Buoyant
Convection in Geophysical Flows, Kluwer, 504 pp.
103. Ribeiro, J. C., P. Kastner-Klein, and E.
Fedorovich, 1999: Wind tunnel study of flow fields in street canyons with
moving vehicles. Abstr. Third SATURN Workshop,
23-24 September 1999,
104. Scipión, D., A. M. Botnick, P. B. Chilson, E.
Fedorovich, and R. D. Palmer, 2008a: Evaluation of
averaging strategies for the retrieval of convective boundary layer turbulence
parameters. Proc. 14th International Symposium for the Advancement of Boundary Layer Remote
Sensing, June
23-25, 2008,
105. Scipión, D., P. B. Chilson, E.
Fedorovich, and R. D. Palmer, 2006a: Characterization of the daytime convective
boundary layer using an advanced radar simulator. Proc. 7th Internat. Symp. on Tropospheric Profiling, June 7-11,
2006,
106. Scipión, D., P. Chilson, E. Fedorovich,
and R. Palmer, 2006b: Advanced radar simulator for the daytime atmospheric convective boundary
layer. Abstr. 13th International Symposium for
the Advancement of Boundary Layer Remote Sensing, July 17-20, 2006,
107. Scipión, D., P. B. Chilson, E. Fedorovich, and R.
D. Palmer, 2008b: Evaluation of an LES-based wind profiler simulator
for observations of a daytime atmospheric convective boundary layer. J.
Atmos. Oceanic Technol., 25, 1423-1436. JTECH
2008 Scipion et al.pdf
108. Scipión, D., E. Fedorovich, A. Botnick,
R. D. Palmer, and P. Chilson, 2008c: Radar measurements of turbulence parameters in
the convective boundary layer. Poster at
the 2008 CEDAR Workshop, June 15-11, 2008, Midway,
109. Scipión, D., E. Fedorovich, R. Palmer, P.
Chilson, and A. M. Botnick, 2009a: Turbulence kinetic energy and dissipation
rate estimated from a virtual wind profiler and verified through large-eddy
simulations. Preprints, 34th Conference on Radar Meteorology, Amer.
Meteor. Soc., 5-9 October, Williamsburg, Virginia, USA, 4B.3. 34th
AMS Radar Met 2009 Scipion et al.pdf
110. Scipión, D., R. D. Palmer, P. B. Chilson, E.
Fedorovich, and A. M. Botnick, 2009b: Retrieval of convective
boundary layer wind field statistics from radar profiler measurements in
conjunction with large eddy simulation. Meteorologische Zeitschrift, 18,
175-187. MZ
2009 Scipion et al.pdf
111. Scipión, D., R. D. Palmer, P. B. Chilson, E.
Fedorovich, R. J. Doviak, G. Zhang, and A. M. Botnick, 2009c: Effects of
horizontal shear of vertical velocity in DBS and SA mean wind estimates revealed
by a combination of LES and virtual radar. Proc.
25th Internat. Conf. on Interactive Information and Processing Systems for
Meteorology, Oceanography, and Hydrology, January 12-15, 2009,
112. Scipión, D., R. D. Palmer, E. Fedorovich, P. B.
Chilson, and A. M. Botnick, 2007: Structure of a daytime convective boundary layer
revealed by a virtual radar based on large eddy simulation. Preprints, 33rd Conference on Radar Meteorology, Amer.
Meteor. Soc., 6-10 August, Cairns, Australia, CD-ROM, 13B.3. 33rd
AMS Radar Met 2007 Scipion et
al.pdf
113. Shapiro, A., and E. Fedorovich, 2003: Pressure work effects in unsteady convectively driven flow along a
vertical plate. Proc. 3rd Intern. Conf. on Computational Heat and Mass Transfer, 26-30 May
2003,
114. Shapiro, A., and E. Fedorovich, 2004a: Unsteady convectively driven flow along a
vertical plate immersed in a stably stratified fluid. J. Fluid Mech., 498, 333-352. JFM
2004 Shapiro & Fedorovich.pdf
115. Shapiro, A., and E. Fedorovich, 2004b: Prandtl-number
dependence of unsteady natural convection along a vertical plate in a stably
stratified fluid. Int. J. Heat and Mass Transfer, 47, 4911-4927. IJHMT
2004 Shapiro & Fedorovich.pdf
116. Shapiro, A., and E. Fedorovich, 2005a: Analytical and numerical study of natural convection in a stably
stratified fluid along vertical plates and cylinders with temporally-periodic
surface temperature variations. Progress in Computational Heat
and Mass Transfers, 1, R.
Bennacer, A. A. Mohamad, M. El Ganaoui, J. Sicard, Eds., Lavoisier, 77-82. Progress
Comp. Heat Mass Transfer 2005 Shapiro & Fedorovich.pdf
117. Shapiro, A., and E. Fedorovich, 2005b: Katabatic flow along a
differentially cooled sloping surface in a stratified fluid. Preprints, 11th AMS Conference on Mesoscale Processes,
Amer. Meteor. Soc., 24-29 October,
118. Shapiro, A., and E. Fedorovich, 2006: Natural convection in a stably stratified fluid
along vertical plates and cylinders with temporally-periodic surface
temperature variations. J. Fluid Mech., 546, 295-311. JFM
2006 Shapiro & Fedorovich.pdf
119. Shapiro, A., and E. Fedorovich, 2007a: Katabatic flow along a differentially cooled
sloping surface. J. Fluid Mech., 571, 149-175. JFM
2007 Shapiro & Fedorovich.pdf
120. Shapiro,
A. and E. Fedorovich, 2007b: Coriolis effects in
inhomogeneous katabatic flows. Abstr. 16th
AMS Conference on Atmospheric and Oceanic Fluid Dynamics, 25-29 June
2007, Santa Fe, New Mexico, USA.
121. Shapiro, A., and E. Fedorovich, 2007c: Analytical and numerical
studies of natural convection along doubly infinite vertical plates in
stratified fluids. Proc. 5th Baltic
Heat Transfer Conference, 2,
19-21 September 2007, Saint Petersburg, Russia, 250-269. 5th
BHTC 2007 Shapiro & Fedorovich.pdf
122.
Shapiro, A., and E. Fedorovich, 2008a: Coriolis effects in homogeneous and
inhomogeneous katabatic flows. Q. J. R. Meteorol. Soc., 134, 353-370. QJRMS
2008 Shapiro & Fedorovich.pdf
123.
Shapiro, A., and E. Fedorovich, 2008b: Coriolis effects in heterogeneous katabatic flows. Abstr.
18th AMS Symposium on Boundary Layers and Turbulence, June 9-13, 2008,
124. Shapiro,
A., and E. Fedorovich, 2009a: Nocturnal low-level jet
over a shallow slope.
Acta Geophysica, 57, 950-980. AG
2009 Shapiro & Fedorovich.pdf
125. Shapiro,
A., and E. Fedorovich, 2009b: Analytical study of a nocturnal low-level jet over a shallow slope. Proc. XIX Congrès
Français de Mécanique,
126. Shapiro,
A., and E. Fedorovich, 2009c: Boundary layer flows along sloping surfaces. Preface to
special issue of Acta Geophysica, 57,
801-802. AG
2009 Preface Shapiro & Fedorovich.pdf
127. Shapiro, A., C. Wall, and E. Fedorovich, 2006: Coriolis effects
in katabatic flow along a differentially cooled sloping surface in a stratified
fluid. Abstr.
17th AMS Symposium on Boundary Layers and Turbulence, May 22-25, 2006,
128. Sokolova, G. P., and E. E. Fedorovich, 1991:
Application of the numerical model for the calculation of turbulent fluxes and
profiles of meteorological values in the atmospheric surface layer on the basis
of standard meteorological observations. Trudy
GGO, 530, 100-108, in Russ.
English abstract in MGA (1992), 43:9-74.
129. Timanovskaya, R. G., and E. E. Fedorovich,
1983: An algorithm of the heat balance components automated control. Trudy GGO, 473, in Russ.
130. Thäter J., and E. Fedorovich, 1999: A wind
tunnel study of gaseous-tracer dispersion in the convective boundary layer
capped by a temperature inversion. Abstr.
EC391 EUROMECH Colloq. on Wind Tunnel Modelling of Dispersion in Environmental
Flows. 13-15 September 1999,
131. Thäter, J., E. Fedorovich, and G. Jirka, 2001: A
combined numerical and laboratory study of dispersion from a point source in
the atmospheric convective boundary layer with wind shear. Proc. Third
Intern. Symp. on Environmental Hydraulics, 5-8 December 2001,
132. Thäter, J., E. Fedorovich, and E. J.
Plate, 2002: Windkanaluntersuchung der Turbulenzdynamik, Transportprozesse und
Ausbreitungsvorgänge in konvektiven Grenzschichten mit angehobener
Temperaturinversion. Endbericht. Institut für
Wasserwirtschaft und Kulturtechnik (IWK), Universität Karlsruhe, 53 pp.,
(available from IWK, Universität Karlsruhe, Kaiserstraße 12, 76128
Karlsruhe, Germany).
133. Vager, B. G., L. Yu. Preobrazhensky, and E. E.
Fedorovich, 1987: Investigation of the hydrometeorological processes over the
sea gulf. Abstr. All-Union Conf.,
134. Vager, B. G., L. Yu. Preobrazhensky, and E. E.
Fedorovich, 1989: Mathematical modelling of the hydrophysical and transformation
processes in a shallow gulf and over coastal area. Abstr. Conf. on Complex Automatization of Hydrophysical Studies,
135. Vager, B. G., L. Yu. Preobrazhensky, and E. E.
Fedorovich, 1991a: Numerical modelling of the atmospheric boundary layer over
the
136. Vager, B. G., D. B. Stavinski, and E. E. Fedorovich,
1991b: Numerical modelling of the atmospheric boundary layer over the northern
coast of
137. Weiss, C. C., H. B. Bluestein, R. Conzemius, and E.
Fedorovich, 2007: Variational pseudo-multiple-Doppler wind retrieval in
the vertical plane for ground-based mobile radar data. J. Atmos. Oceanic
Technol., 24, 1165-1185. JTECH
2007 Weiss et al.pdf
138. Zilitinkevich, S. S., E. E. Fedorovich, and M.
V. Shabalova, 1991a: Calculation of the atmospheric planetary boundary layer
diurnal cycle. Izvestiya AN SSSR, Fizika
Atmosfery i Okeana, 27, 339-352,
in Russ. Engl. translation in Izvestiya, Atmospheric and Oceanic Physics,
Wash., D.C. Available from NTIS, Springfield, VA 22161, MGA (1992), 43:11-153.
139. Zilitinkevich, S. S., E. E. Fedorovich, and M.
V. Shabalova, 1991b: Diurnal cycle of the atmospheric planetary boundary layer.
Modelling Air-Lake Interaction. Physical
Background, S. S. Zilitinkevich, Ed., Springer-Verlag, 30-49.
140. Zilitinkevich, S. S., E. E. Fedorovich, and D.
V. Mironov, 1992a: Turbulent heat transfer in stratified geophysical flows. Recent Advances in Heat Transfer, B.
Sunden and A. Zukauskas, Eds., Elsevier Science Publishers, 1123-1139.
141. Zilitinkevich, S. S., E. E. Fedorovich, and M.
V. Shabalova, 1992b: Numerical model of a non-steady atmospheric planetary
boundary layer, based on similarity theory. Bound.
Layer Meteor., 59, 387-411. BLM
1992 Zilitinkevich et al.pdf
Articles
submitted/accepted/in press
Burkholder,
B., E. Fedorovich, and A. Shapiro, 2009: Evaluating subgrid-scale
models for large-eddy simulation of turbulent katabatic flow. Accepted in Proc. Quality and Reliability of Large-Eddy
Simulations II,
Mironov, D., and
Axelsen, S., A. Shapiro,
Shapiro,
A., and E. Fedorovich, 2009: Analytical description of
a nocturnal low-level jet. Submitted to Q. J. R. Meteorol.
Soc.