Curriculum Vitae    Yuliya I. Troitskaya
Citizenships                           Russian
Date and place of birth:       June 04, 1961; Nizhegorodskaya oblast’, Russia

Affiliation and address:
Department of Geophysical Research, Institute of Applied Physics of Russian Academy of Science; 46 Ul'yanov Street , 603950, Nizhny Novgorod, Russia

Advanced School of General and Applied Physics, Lobachevsky State University of Nizhni Novgorod; 46 Ul'yanov Street , 603950, Nizhny Novgorod, Russia

Laboratory of ocean-atmosphere interaction, A.M.Obukhov Institute of Atmospheric Physics Russian Academy of Sciences; Pyzhyovskiy lane, 3, Moscow, Russia

Phone: 7-831-436-8297 (IAP) Fax:   7-831-436-5976
E-mail:            yuliya@hydro.appl.sci-nnov.ru
URL: www.iapras.ru/english/structure/asist/

Status:
• Head of Department of nonlinear geophysical processes, Institute of Applied Physics RAS (full-time position).
• Professor, Advanced School of General and Applied Physics, Lobachevsky State University of Nizhni Novgorod (part-time position).
• Leading Scientist, Laboratory of ocean-atmosphere interaction, A.M.Obukhov Institute of Atmospheric Physics Russian Academy of Sciences, Moscow (part-time position)

Education and grades:
1999    D.Sc. (Doctor of Phys. & Math. Sc.)
1987    Ph.D. (Candidate of Phys. & Math. Sc.)
1983    Diploma with distinction (M.S.), Physics and Mathematics (Radiophysics), N.I.Lobachevsky Gorky State University,

Professional record:

1987 – 1991    Junior Researcher       Institute of Applied Physics RAS
1991 – 2003    Senior Researcher       Institute of Applied Physics RAS
2003-present   Head of Department of nonlinear geophysical processes     Institute of Applied Physics RAS

Honours and awards:

Member of Academia Europaea (Earth and Cosmic Sciences, since 2007)
Holder of Grant of Russian Science Support Foundation for D.Sc. (2000-2003)
Holder of Grant of President of Russian Federation (2000-2002)
Award of MAIK Nauka/Interperiodica publishes for the best publication (2008)

Research interests:
- Waves, turbulence and flows in marine atmospheric boundary layer and upper ocean, nonlinear surface waves, air-sea interaction at extreme weather conditions.
- Remote sensing methods for diagnostics boundary layers of atmosphere and ocean, satellite remote sensing of natural hazards.
- Laboratory modeling of marine atmospheric boundary layer and upper ocean

Publications and participation in conferences
About 60 peer-reviewed papers, more than 10 invited lectures at international conferences

Professional activities (selected)

• Editorial Boards of Izvestiya Atmospheric and Ocean Physics (Russian, since 2006);
• Editorial Board of “Fundamental and Applied Hydrophysics” (Russian, since 2009)
• Referee of Russian Foundation for basic Research (RFBR), Russian Science Foundation and national Ministry of education
• Editorial Board of Earth Science of RFBR
• Research Council of Institute of Applied Physics RAS and the Advanced School
  of General and Applied Physics at NNSU (Russia)
• Dissertation Council at Institute of Applied Physics RAS
• Dissertation Council at Nizhny Novgorod Technical University
• Guest editor of Nonlinear Processes in Geophysics (2013)
• Expert of Russian Ministry of Education and Science. Certificate No. 06-02007 of 29.08.2012
• Reviewer of J Fluid Mechanics; Nonlinear Processes in Geophysics; Geophysical Research Letters; J. Geophysical Research; International Journal of Remote Sensing; Izvestiya, Atmospheric and Oceanic Physics; Radiophysics and Quantum Electronics, Fundamental and Applied Hydrophysics.

Supervision of Ph.D. Theses (5):
1. Reznik S.N. Resonant effects of excitation waves in stratified shear flows (Radiophysics). Institute of Applied Physics, Gorky, 1997.
2. Sergeev D.A. “Laboratory studying of surface and inner flows in the ocean with digital velocimetry methods” (Physics of atmosphere and hydrosphere). Institute of Applied Physics, Nizhny Novgorod, 2006.
3. Ermakova O.S. “Physical modeling of interaction of nonlinear surface waves and turbulence in boundary layers of ocean and atmosphere” (Physics of atmosphere and hydrosphere). Institute of Applied Physics, Nizhny Novgorod, 2010.
4. Ezhova E.V. «Non-stationary dynamics of buoyant plumes in stratified fluid» (Physics of atmosphere and hydrosphere). Institute of Applied Physics, Nizhny Novgorod, 2011.
5. Kandaurov A.A. Laboratory modelling of wind-wave interaction under strong wind conditions  (Physics of atmosphere and hydrosphere). Institute of Applied Physics, Nizhny Novgorod, 2014.

Lecturing in Russia and abroad:
Nizhny Novgorod State University (Russia):

• Fluid Dynamics (1998-2014);
• Physical oceanography (2005-2014)

Nizhny Novgorod State Technical University (Russia):

• Fluid Dynamics (2000 - 2008);

Ruprecht-Karls-University of Heidelberg (Germany)

• Turbulent boundary layer (2012)

Joint COSPAR and WMO Capacity Building Workshop on "Satellite remote sensing, water cycle and climate change" (Russia)

• Satellite remote sensing of hurricanes
• Altimetry of inland waters

Active research grants, principal investigator
• Air-Sea Interaction under Stormy and Hurricane Conditions: Physical Models and Applications to Remote Sensing” FP7-PEOPLE-2013-IRSES, 2014-2017. , Project No. 612610
• Численные,  физические  и теоретические модели взаимодействия волн, течений и турбулентности в пограничных слоях атмосферы и океана. Project 5.2 of the National Program “Fundamental Problems of Nonlinear Dynamics”. Russian Academy of Sciences. 2006-2014.
Радиофизические методы дистанционной диагностики процессов в пограничных слоях океана и атмосферы прибрежной зоны и внутренних водоемов. National Program “Fundamental Problems of Oceanography”. Russian Academy of Sciences. 2006-2014.
• Wind-wave interaction and scattering of radio waves on the sea surface at extremely high winds: the physical and numerical modeling. Russian Foundatio for Basic Research, 13-05-00865. 2013-2015.
• Development of methods for estimating parameters of atmospheric and oceanic boundary layers in Emergency Situations of natural and artificial origin by satellite remote sensing comprehensive data and GIS-technologies. Russian Foundation for Basic Research 13-05-12093. 2013-2015.
• Investigation of hydrophysical processes in the lake part of lowland reservoirs (on an example of Gorky reservoir). Russian Foundation for Basic Research, 13-05-97068, 2013-2014.
Dynamics and remote sensing of multiphase media in the boundary layers of the atmosphere and
Hydrosphere National Science Foundation, 14-17-00667, 2014-2016.
Research profile
Top-12 papers of Yu.Troitskaya develop a comprehensive theoretical model of marine atmospheric boundary layer in wide range of wind conditions up to hurricanes [1*,5*,9*] and wind stress modulation mechanism of surface manifestations of processes in the upper ocean [4*,6*,7*]; pioneering experiments on fine structure of air flow over steep surface waves [10*,11*]; experimentally confirmed mechanism of anomalously low aerodynamic resistance of the water surface [12*]; pioneering studies of and turbulence in stratified flows, including theory of nonlinear critical layer in stratified shear flow [3*], turbulent closure in a stratified turbulent fluid based on equation for probability density function of velocity and density fluctuations [2*], a theory of a turbulent wake behind an obstacle in a stratified flow [8*].
   Extreme storms and hurricanes represent a major challenge to society worldwide. The importance of storm hazard grows sharply because of the steep increase of population in coastal areas, expansion of the all form of the off-shore activities and maritime trade. The accuracy of existing wave models under stormy condition is relatively low (does not exceed 30%), it is especially poor for the severe storms. One of their key shortcomings is their inability to account for the effect of low sea surface aerodynamic drag observed under very strong winds. This calls for parameterization of air-sea interaction under stormy conditions. A promising way here is development of theoretical models confirmed by physical and numerical experiments.
Yu.Troitskaya has developed a theoretical model of a turbulent boundary layer over the sea [1*,5*,9*], which key feature is the mutual feedback between the wind and surface waves in a wide range of scales considered within the quasi-linear approximation. To test the key supposition of the model, she, together with together with PhD students and post-docs, have carried out pioneering laboratory experiments on investigation of atmospheric boundary layer over steep surface waves with the use of modern imaging techniques of air flow (PIV) [10*], and conducted a direct numerical simulation of wind over a steep wave [11*]. The basic conclusion of both physical and numerical experiments was the proof of the un-separated character of the flow of air flow over surface wave averaged over the turbulent pulsations, which confirms the applicability of quasi-linear (Stokes) approximation to describe the interaction of wind and waves. It establishes then, that of the sea surface roughness is determined only by the spectrum of the surface waves - easily quantifiable and calculable quantities. This significantly simplifies the modeling of the sea surface roughness, which is now defined only by the spectrum of the surface waves - easily measurable quantity.
Under the leadership of Yu.Troitskaya a high wind-wave flume was designed and constructed in IAP RAS for investigation air-sea interaction under gale-force wind. It is the only facility in Europe allowing modelling conditions typical for tropical and polar storms, severe storms, tornadoes or squall lines, accompanied by winds of up to 40 m/s. In this facility, pioneering experiments directed to investigation of wind-wave interaction under hurricane conditions were carried out [12*]. These experiments elucidated the mechanism of abnormally low resistance of the ocean surface at hurricane wind speeds due to mechanical smoothing of the water surface by strong winds, tearing of crests of steep waves.
The proposed and developed by Yu.Troitskaya model of turbulent boundary layer over the rough water surface has found numerous applications for the explanation and the parameterization of the observed phenomena in marine atmospheric boundary layer. In particular, based on calculations within the model, she proposed a simple parameterization of the drag coefficient and the growth rate of the surface waves on the wind speed and wave parameters, applicable in a wide range of wind speeds and wave parameters [9*]. Also, based on the model, a new mechanism of surface manifestations of processes in the upper ocean due to the modulation of the short surface waves wind pumping (stress modulation mechanism) was proposed and investigated [4*]. Consideration of the stress modulation mechanism in the model of radio image of inhomogeneous surface currents cause by swell, internal waves, bottom topography, explained a number of features (e.g. abnormally high hydrodynamic contrasts), which are not reproduced by the traditional mechanism of adiabatic transformation of surface waves on non-uniform currents [6*]. The proposed stress modulation mechanism allowed Yu.Troitskaya to explain modulation of radar backscatter of water surface caused by tsunami from the catastrophic Sumatra earthquake, December 26, 2004, which she discovered on the basis of the analysis of geophysical data record of altimetry satellite Jason-1 [7*].
Yu.Troitskaya also obtained a series of pioneering results in the theory of interaction of non-linear waves and turbulent flows. She developed an asymptotic theory of nonlinear interaction of internal gravity waves with a dynamically stable stratified shear flow in the critical layer, where a significant non-linear, and diffusion effects (viscosity, thermal conductivity) [3*]. This object has long been an important unsolved problem in the theory of wave interaction with geophysical flows. In her pioneering work Yu.Troitskaya has shown that the absorption intensity of the internal wave in the critical layer caused strong deformation of the flow and led to its destabilization [3*]. She also has developed the first version of a turbulent closure in a stratified turbulent fluid, taking into account both forward and reverse exchange between kinetic and potential components of the turbulent energy and explain the maintenance of turbulence in strongly stratified flows [2*]. Based on these studies, she was first proposed a theoretical model of a turbulent wake behind an obstacle in a stratified flow, based on the nonlinear theory of hydrodynamic flow instability in the wake [8*]. The model accurately agrees with the experimental data and a direct numerical simulation.
Over the last 5 years Yu.Troitskaya has published 20 peer-reviewed papers in international and national Russian (translated) journals. The basic achievement of this period are: 1) Pioneering experiments on wind-wave interaction under hurricane wind conditions; an experimentally verified physical mechanism of low aerodynamic resistance of the ocean surface at hurricane winds [36, 51]; 2) Experimental investigation and development of theory of excitation of internal waves due to self-sustained oscillations of buoyant plumes interacting with the thermocline [37-40, 44, 52-55, 60]; 3) Experimental investigation of fine structure of air flow in the turbulent boundary layer over steep waves by PIV-technique [42, 43, 45] and DNS [48] revealed non-separated flow over steep waves averaged over turbulent fluctuations. It allows quasi-linear approximation of wind-wave interaction

List of 12 most significant papers

1* Yu.I. Nicolaeva (Troitskaya), L.Sh.Tsimring A kinetic model of surface wave generation by turbulent wind Izvestiya RAN Atmospheric and Ocean Physics, 1986, V.22, №2, p.135-142

2* L.A.Ostrovsky, Yu.I.Troitskaya Model of turbulent transition and turbulence dynamics in stratified shear flow. Izvestiya RAN Atmospheric and Ocean Physics, 1987, v.23, №10, p, 1031-1040

3* Yu.I.Troitskaya Viscous diffusion nonlinear critical layer in a stratified shear flow  Journal of Fluid Mechanics, v.233, 1991, p.25-48

4* Yu.I.Troitskaya Modulation of the growth rate of short capillary-gravity wind waves by a long wave  Journal of Fluid Mechanics, v.273, 1994, p.169-187

5* Reutov V.P., Troitskaya Yu.I.. About nonlinear effects of interaction between surface waves and turbulent wind // Izv. ,Atmospheric and Oceanic physics 1995, V.31, Pt 5, P.825–834.

6* K.A. Gorshkov, I.S. Dolina and I.A. Soustova, Yu.I.Troitskaya  Transformation of short waves in the field of inhomogeneous flows at the ocean surface Effect of the wind growth rate modulation. Radiophysics and Quantum Electronics, v.46, N7, p.513-536, 2003

7* Yu.I.Troitskaya, S.A. Ermakov, Manifestations of the Indian Ocean tsunami of 2004 in satellite nadir-viewing radar backscatter variations  Geophys.Res.Letters (2006), V. 33, LXXXXX, doi:10.1029/2005GL024445, 2006

8* Yu. I.Troitskaya, D.A.Sergeev, O.A.Druzhinin, V.V.Papko, G.N.Balandina   FA theoretical model of a wake of a body towed in a stratified fluid at large Reynolds and Froude numbers  Nonlinear Processes in Geophysics, v.13, p.247-253, 2006.

9* Yu. I. Troitskaya and G. V. Rybushkina. Quasi-Linear Model of Interaction of Surface Waves with Strong and Hurricane Winds Izv..Atm. and Oceanic Phys...2008. v. 44. N4. С. .621-645

10* Troitskaya Yu. I., Sergeev D. A., Ermakova O. S., and Balandina G. N. Statistical Parameters of the Air Turbulent Boundary Layer over Steep Water Waves Measured by the PIV Technique // J. Physical Oceanography. 2011.,V. 41, p.1421-1454.

11* Druzhinin, O. A., Y. I. Troitskaya, and S. S. Zilitinkevich (2012), Direct numerical simulation of a turbulent wind over a wavy water surface, J. Geophys. Res., 117, C00J05, doi:10.1029/2011JC007789.

12* Troitskaya, Y. I., D. A. Sergeev, A. A. Kandaurov, G. A. Baidakov, M. A. Vdovin, and V. I. Kazakov (2012) Laboratory and theoretical modeling of air-sea momentum transfer under severe wind conditions J. Geophys. Res., 117, C00J21, doi:10.1029/2011JC007778

LIST OF SELECTED PUBLICATIONS

1.         L.A.Ostrovsky, Yu.I.Troitskaya Resonant damping of internal waves on random velocity field in the ocean Izvestiya RAN Atmospheric and Ocean Physics, 1986, v.22, №3, p,310-317
2.         L.Sh.Tsimring, Yu.I. Nicolaeva (Troitskaya) A kinetic model of surface wave generation by turbukent wind Izvestiya RAN Atmospheric and Ocean Physics, 1986, V.22, №2, p.135-142
3.         Yu.I.Troitskaya Increasing disturbances of spatially periodic flow of stratified fluid Marine Hydrophysical Journal, 1987, №6, p.13-22
4.         L.A.Ostrovsky, Yu.I.Troitskaya Model of turbulent transition and turbulence dynamics in stratified shear flow . Izvestiya RAN Atmospheric and Ocean Physics, 1987, v.23, №10, p, 1031-1040
5.         L.A.Ostrovsky, Yu.I.Troitskaya Effect of fine structure of velocity field on propagation of internal waves in the ocean Izvestiya RAN Atmospheric and Ocean Physics, 1988, v.24, №7, p,753-763
6.         N.I.Vasilinenko, S.A.Ermakov, A.V.Idfyjd, A.R.Pahchenko, S.G.Salashin, Yu.I.Troitskaya Manifestation of internal waves at the water surfacein the presence of surfactant  Doklady Earth Sciences, Vol 307, No 5. pp.1235-1238 1989
7.         Yu.I.Troitslkaya, A.L.Fabricant Resonant interaction of internal gravity waves in stratified shear flow Radiophysics and Quantum Electronics, v.32, N 12,с.1221-1231, 1990
8.         Yu.I.Troitskaya Viscous diffusion nonlinear critical layer in a stratified shear flow  Journal of Fluid Mechanics, v.233, 1991, p.25-48
9.         Yu.I.Troitskaya Modulation of the growth rate of short capillary-gravity wind waves by a long wave  Journal of Fluid Mechanics, v.273, 1994, p.169-187
10.       V.A.Ivanov, E.N.Pelinovsky, T.T.Talipova, Yu.I.Troitskaya Statistical estimations of nonlinear long internal wave parameters at the polygon of SCC in the Black Sea Marine Hydrophysical Journal, 1994, №4, p.9-27
11.       Reutov V.P., Troitskaya Yu.I.. About nonlinear effects of interaction between surface waves and turbulent wind // Izv. ,Atmospheric and Oceanic physics 1995, V.31, Pt 5, P.825–834.
12.       S.N.Reznik, Yu.I Troitskaya Wave drag of a local bottom elevation in a stratified shear flow with a critical layer. Izvestiya RAN Atmospheric and Ocean Physics, v.32, N 1, 1996, p. 133-140
13.       S.N.Reznik, Yu.I.Troitskaya Quasi-steady dissipative nonlinear critical layer in a stratified shear flow  Phys.Fluids v.8, N12, 1996, p.3313-3328 34
14.       V.P.Reutov, Yu.I.Troitskaya Nonlinear growth rate of water waves under turbulent atmospheric boundary layer and their excitation near stability Radiophysics and Quantum Electronics . v.38. N3-4. p.206-210, 1996.
15.       Yu.I.Troitskaya  Mechanism of modulation of the growth rate of short surface waves excited by turbulent wind Izvestiya RAN Atmospheric and Ocean Physics. 1997. v.33. N4. p.525-535.
16.       S.N.Reznik, Yu.I Troitskaya wave drag of a mass source in a stratified shear flow with a critical layer. Two-dimensional case. Fluid Dynamics, v.32, N2, 1997.
17.       Yu.I.Troitskaya An evolutionary equation for weakly nonlinear wind waves on the surface of a finite-depth viscous fluid. Izvestiya RAN Atmospheric and Ocean Physics. , v.33, N3, p.364-375/ 1997.
18.       S.N.Reznik, Yu.I Troitskaya Quasi-linear model of deformation of a stratified three-dimensionally inhomogeneous flow above a randomly inhomogeneous surface. . Radiophysics and Quantum Electronics, v.42, N 3, 1999.
19.       Yu.I.Troitskaya Asymptotic models of diffusion effects due to nonlinear resonant interaction of waves with flows. Radiophysics and Quantum Electronics, v.44, N 5-6, 2001
20.       Kazakov V.I., B.V.Serin and D.P.Korotkov, Talanov V.I., Yu.I.Troitskaya Self-sustained oscillations in the stratified shear flow Izvestiya RAN Atmospheric and Ocean Physics. v.38. №4, p.504-514, 2002.
21.       I.S. Dolina , Yu. I. Troitskaya  On a possible mechanism of signature of the bottom topography at the water surface. Izvestuya PAS Atmospheric and Ocean Physics, v.38, N3, p.1-10, 2002.
22.       N.S.Petrukhin, IA.Soustova, B.Roberts, Yu.I.Troitskaya MHD Waves in the Structured Solar Corona    Izvestiya AIN RF Apllied mathematics and mechanics. 2002. v. 3. p. 23-27.
23.       Ostrovsky L.A.,. N.S.Petrukhin, IA.Soustova, B.Roberts, Yu.I.Troitskaya  On possible mechanism of wave collapse of isolated magnetic tubes Izvestiya AIN RF Apllied mathematics and mechanics. 2002. v.1, p.79-91
24.       K.A. Gorshkov, I.S. Dolina and I.A. Soustova, Yu.I.Troitskaya  Modulation of short surface waves in the presence of intensive internal waves. Effect of stress modulation Izv..Atm. and Oceanic Phys V..39. №15, p.661-672, 2003
25.       K.A. Gorshkov, I.S. Dolina and I.A. Soustova, Yu.I.Troitskaya  Transformation of short waves in the field of inhomogeneous flows at the ocean surface Effect of the wind growth rate modulation. Radiophysics and Quantum Electronics, v.46, N7, p.513-536, 2003
26.       G.V. Balandina, V.V. Papko, D.A. Sergeev, Yu.I. Troitskaya,. Evolution of the far turbulent wake behind a body towed in stratified fluid with large Reynolds and Froude numbers. Izv..Atm. and Oceanic Phys.. 2004. Vol.40. N.1. PP. 99-113.
27.       A.A.Abrashkin, V.S.Averbakh, S.N.Vlasov, Yu.M.Zaslavsky, I.A.Soutova, R.A.Sudarikov, Yu.I.Troitskaya On possible mechanism of acoustical field effect of partially saturated porous media Acoustic journal, v.50, Supplement, p.19-30, 2005
28.       A. I. Zaitsev, A. A. Kurkin, B. V. Levin, E. N. Pelinovsky, A. Yalciner, Yu. I. Troitskaya, and S. A. Ermakov Numerical simulation of propagation of the catastrophic tsunami in the Indian Ocean (December 26, 2004) Doklady Earth Sciences, Vol, No 3, (2005), pp. 388-392.
29.       Yu. I.Troitskaya, D.A.Sergeev, O.A.Druzhinin, V.V.Papko, G.N.Balandina   Far wake of a body towed in a stratified fluid at large Reynolds and Froude numbers   Nonlinear Processes Geophys. V.13 P. 247-253, 2006
30.       Yu.I.Troitskaya, S.A. Ermakov,   Manifestations of the Indian Ocean tsunami of 2004 in satellite nadir-viewing radar backscatter variations  Geophys.Res.Letters (2006), V. 33, LXXXXX, doi:10.1029/2005GL024445, 2006
31.       O.S.Ermakova, S.A.Ermakov, Yu.I.Troitskaya. Laboratory investigation of a turbulent layer excited by standing surface waves Izv..Atm. and Oceanic Phys.. 2006. Vol.42. N.6. PP. 701 -- 703.
32.       O.A. Druzhinin, D.A. Sergeev and Yu.I.Troitskaya Laboratory and numerical modelling of far wake flow in A stratified fluid Izv. Atm. and Oceanic Phys.. 2006. Vol.42. N.5. PP. 668 -- 680.
33.       O. S. Ermakova, S. A. Ermakov, and Yu. I. Troitskaya Laboratory Study of the Dynamics a Layer of Turbulence Excited by Standing Surface Waves, Izv..Atm. and Oceanic Phys...2007. v. 43. N1. С. .81-94.
34.       Yu. I. Troitskaya, S. A. Ermakov Manifestations of the Indian Ocean tsunami of 2004 in satellite nadir-viewing radar backscatter variations" International Journal of Remote Sensing, v.29, N 21, p.6361-6372, 2008.
35.       Yu. I. Troitskaya, I. S. Dolina, A. V. Ermoshkin, V. V. Bakhanov, E. M. Zuikova, I. A. Repina, and V. I. Titov Negative Correlations of Variations in Near-Water Wind and Surface Wind Waves , Izv..Atm. and Oceanic Phys...2008. v. 44. N4. С. .491-506.
36.       Yu. I. Troitskaya and G. V. Rybushkina. Quasi-Linear Model of Interaction of Surface Waves with Strong and Hurricane Winds Izv..Atm. and Oceanic Phys...2008. v. 44. N4. С. .621-645.
37.       Yu. I. Troitskaya, D. A. Sergeev, E. V. Ezhova, I. A. Soustova, and V. I. Kazakov Self-Induced Internal Waves Excited by Buoyant Plumes in a Stratified Tank Doklady Earth Sciences, Vol, No 3, (2008), pp. 506-510. 
38.       V. G. Bondur, Yu. V. Grebenyuk, E. V. Ezhova, V. I. Kazakov, D. A. Sergeev, I. A. Soustova, and Yu. I. Troitskaya Surface Manifestations of Internal Waves Investigated by a Subsurface Buoyant Jet:1. The Mechanism of Internal-Wave Generation Izv..Atm. and Oceanic Phys...2008. v. 45. N6. С. . 779–797.
39.       V. G. Bondur, Yu. V. Grebenyuk, E. V. Ezhova, V. I. Kazakov, D. A. Sergeev, I. A. Soustova, and Yu. I. Troitskaya Surface Manifestations of Internal Waves Investigated by a Subsurface Buoyant Jet:2. Internal Wave Field // Izv..Atm. and Oceanic Phys...2009. v. 46. N3. p. 347–359.
40.       V. G. Bondur, Yu. V. Grebenyuk, E. V. Ezhova, V. I. Kazakov, D. A. Sergeev, I. A. Soustova, and Yu. I. Troitskaya Surface Manifestations of Internal Waves Investigated by a Subsurface Buoyant Jet: 3. Surface Manifestations of Internal Waves // Izv..Atm. and Oceanic Phys...2009. v. 46. N4. p. 482–491.
41.       O. S. Ermakova, Yu. A. Mal’kov, D. A. Sergeev, and Yu. I. Troitskaya Study of Nonlinear Currents Induced by Coincident Surface Waves in Liquid Izv..Atm. and Oceanic Phys...2009. v. 45. N6. С. . 791–798.
42.       Yu. I. Troitskaya, D. A. Sergeev, O. S. Ermakova, and G. N. Balandina Fine Structure of the Turbulent Atmospheric Boundary Layer over the Water Surface Izv..Atm. and Oceanic Phys.2010. v. 46. N1. С. .119-130.
43.       Yu. I. Troitskaya, D. A. Sergeev, O. S. Ermakova, and G. N. Balandina Statistical Properties of the Atmospheric Turbulent Boundary Layer over Steep Surface Waves: Doklady Earth Sciences, 2010, Vol. 433, Part 1, pp. 922–926.
44.       Druzhinin O.A.,  Yu. I. Troitskaya. Generation of internal waves by a fountain in strafified fluid. Fluid Dynamics, 2010. N 3. P. 147-158.
45.       Troitskaya Yu., Sergeev D., Ermakova O., Balandina G. Statistical parameters of the air turbulent boundary layer over steep water waves measured by the DPIV technique // Journal of Physical Oceanography, v 41, N8, p.1421-1453, 2011.
46.       Yuliya Troitskaya, Daniil Sergeev, Alexander Kandaurov and Vasilii Kazakov. {\it Air-sea interaction under hurricane wind conditions} in "Recent Hurricane Research - Climate, Dynamics, and Societal Impacts" ISBN 978-953-307-238-8 Book edited by: Prof. Anthony Lupo 2011. p .247-268.
47.       Yu. Troitskaya , G. Rybushkina , I. Soustova, G. Balandina, S. Lebedev, and A. Kostianoy Adaptive retracking of Jason-1 altimetry data for inland waters on the example of the Gorky Reservoir International Journal Remote Sensing, 2012 v.33, N 23, p. 7559-7578, 2012.
48.       1. Druzhinin, O. A., Y. I. Troitskaya, and S. S. Zilitinkevich (2012), Direct numerical simulation of a turbulent wind over a wavy water surface, J. Geophys. Res., 117, C00J05, doi:10.1029/2011JC007789.
49.       S. S. Zilitinkevich, S. A. Tyuryakov, Yu. I. Troitskaya, and E. A. Mareev Theoretical Models of the Height of the Atmospheric Boundary Layer and Turbulent Entrainment at Its Upper Boundary. Izvestiya, Atmospheric and Oceanic Physics, V. 48, N1, стр.133-145, 2012.
50.       Yu. I. Troitskaya, G. V. Rybushkina, I. A. Soustova, G. N. Balandina, S. A. Lebedev, A. G. Kostyanoi, A. A. Panyutin, L. V. Filina Satellite Altimetry of Inland Water Bodies. Water Resources.V. 39, N2, P. 161-179 , 2012
51.       Troitskaya, Y. I., D. A. Sergeev, A. A. Kandaurov, G. A. Baidakov, M. A. Vdovin, and V. I. Kazakov Laboratory and theoretical modeling of air-sea momentum transfer under severe wind conditions J. Geophys. Res., 117, C00J21, doi:10.1029/2011JC007778
52.       E. V. Ezhova, Yu. I. Troitskaya Nonstationary dynamics of turbulent axisymmetric jets in a stratified fluid: Part 2. Mechanism of excitation of axisymmetric oscillations in a submerged jet Izvestiya, Atmospheric and Oceanic Physics Volume 48, Issue 5 , pp 528-537, 2012
53.       E. V. Ezhova, D. A. Sergeev, A. A. Kandaurov, Yu. I. Troitskaya Nonsteady dynamics of turbulent axisymmetric jets in stratified fluid: Part 1. Experimental study     Izvestiya, Atmospheric and Oceanic Physics Volume 48, Issue 4 , pp 409-417, 2012
54.       V. Bondur, Yu.Grebenyuk, E. Ezhova, A.Kandaurov, D. Sergeev and Yu.Troitskaya Applying of PIV/PTV Methods for Physical Modeling of the Turbulent Buoyant Jets in a Stratified Fluid in the book "The Particle Image Velocimetry - Characteristics, Limits and Possible Applications" edited by Giovanna Cavazzini, ISBN 978-953-51-0625-8, InTech, May 5, 2012, pp. 155-180.
55.       Druzhinin O.A., Troitskaya Yu. I. Regular and chaotic dynamics of a  fountain  in a stratified fluid // CHAOS. 2012. V. 22, 023116; doi:10.1063/1.4704814. 14PP.
56.       Yu. I. Troitskaya, G. V. Rybushkina, I. A. Soustova, S. A. Lebedev Adaptive Retracking of Jason-1, 2 Satellite Altimetry Data for the Volga River Reservoirs Selected Topics in Applied Earth Observations and Remote Sensing, IEEE Journal, issue 99, 2013, doi: 10.1109/JSTARS.2013.2267092
57.       Troitskaya, Y. I., E. V. Ezhova, S. S. Zilitinkevich (2013) Momentum and buoyancy exchange in a turbulent air boundary layer over a wavy water surface. Part 1. A harmonic wave, Nonlinear Processes in Geophysics v.20, 2013
58.       Yu. I. Troitskaya, E. V. Ezhova, D. A. Sergeev, A. A. Kandaurov, , G. A. Baidakov, M. A. Vdovin, S. S. Zilitinkevich (2013) Momentum and buoyancy exchange in a turbulent air boundary layer over a wavy water surface. Part 2. Wind wave spectra Nonlinear Processes in Geophysics v.20, 2013
59.       I. Esau, T. Wolf, E. Miller, I. Repina, Y. Troickaya, S. Zilitinkevich Analysis of remote sensing monitoring of the lower atmosphere temperature profile in Bergen, Norway, 10, 93-103, Meteorologia i Gidrologia
60.       Druzhinin O.A., Troitskaya Excitation of internal waves by a turbulent fountain in stratified fluid. Fluid Mechanics, N6, 2013, pp.122-132.