Vladimir Dubrovskii Explained

Vladimir G. Dubrovskii
Birth Date:1965 10, df=yes
Citizenship:Russia
Fields:Condensed matter physics
Semiconductor nanostructures and nanowires
Classical nucleation theory
Workplaces:St. Petersburg Academic University
Ioffe Institute
St. Petersburg State University
ITMO University
Alma Mater:St. Petersburg State University
Leningrad State University (diploma, 1988)
Known For:Theoretical physics and Physics of nanostructures

Vladimir G. Dubrovskii (Russian: Владимир Германович Дубровский; born in 1965) is the head of Laboratory of physics of nanostructures at St. Petersburg Academic University,[1] a leading research scientist at Ioffe Institute,[2] and a professor at St. Petersburg State University and ITMO University.[3]

Educational background

Dubrovskii graduated from St. Petersburg State University, Department of Statistical Physics, in 1988, with a diploma in theoretical physics. In 1991, he was a post-doc research fellow in Oxford University. He obtained his PhD in 1990 and a doctor of sciences degree in 2002, in condensed matter physics.

Contributions to physics

Dubrovskii has made contributions to several fields of physics.

Semiconductor nanostructures and nanowiresHe is best known for growth modeling of semiconductor nanostructures, particularly III-V nanowires. Starting from 2003, he has been at the forefront of research in this field, collaborating with more than 40 groups in 18 countries (with joint publications). His main area is in kinetically controlled engineering of nanostructures, including morphology, crustal phase, and size distributions. In 2005, he and coauthors proved a diffusion-induced character of gold-assisted vapor-liquid-solid (VLS) growth of GaAs nanowires by molecular beam epitaxy [1]. In 2008-2014, following Frank Glas [2], he developed theoretical approaches for understanding and controlling polytypism of III-V nanowires by the growth parameter tuning [3] and catalyst material [4]. This allowed achieving record small GaAs nanowires (down to 5 nm in radius) with pure zincblende structure [5]. Independently of Jerry Tersoff [6], in 2013-2015 he predicted a non-linear focusing effect [7,8] that enabled self-organized ensembles of GaAs nanowires with uniform radii [8]. The works of 2016 brought up the new size distributions describing length statistics in nanowire ensembles [9,10]. In 2015-2016, he developed the first theory for the compositional control of ternary III-V nanowires [11], sharpening their axial heterointerfaces [12] and, more generally, nucleation theory of ternary solids from ternary and quaternary liquid alloys. He contributed into understanding the VLS versus selective area growth of nanowires [13] and self-induced nucleation of GaN nanowires on silicon substrates [14].
Classical nucleation theoryIn 2009, Dubrovskii discovered fluctuation-induced broadening (the Dubrovskii broadening) of the size distributions described by a Fokker-Planck type kinetic equation in terms of the Kuni invariant variables [15], and presented a map of the power exponents for the spectrum spreading in 2D and 3D systems. Further studies revealed the influence of kinetic fluctuations on the size distributions of islands and droplets in the stages of their nucleation, growth, and Ostwald ripening [16,17]. He also contributed into binary nucleation theory with a saddle point of the formation energy, with applications in growth theory of strain-induced islands [18] and ternary VLS nanowires.
  • Statistical size distributions and scaling propertiesIn 1996, he published exact solution for the infinite set of rate equations for heterogeneous growth with size-linear rate constants [19], reduced to one-parametric Polya distribution. Further investigation of the growth systems with size-linear capture rates led to a two-parametric modified beta-distribution (2015) [20] which acquires the Vicsek-Family scaling form [21] in the continuum limit. Distributions of this type are now widely used for modeling the growth kinetics of semiconductor nanostructures, surface islands and biological objects.
  • Self-regulated nucleation and growth in nanosystemsSince 2004, Dubrovskii pursued growth theories in confined systems with a limited amount of growth species in the mother phase. He developed concepts of “mononuclear” growth [22,23] whereby individual nucleation events predetermine physical properties of emerging nanomaterials. He developed methods of using different size-dependent effects for narrowing size distributions [8,24-26].
    Together with Frank Glas, he predicted narrow sub-Poissonian size distributions [27] in systems with nucleation antibunching [28], and derived analytical asymptotes for their time-independent shapes.
  • Elastic relaxation and plastic deformation in nanostructuresHe and coauthors developed semi-analytical models for elastic relaxation and misfit dislocations in nanostructures grown on lattice-mismatched substrates [29] and contributed into development of epitaxial techniques for monolithic integration of high quality optical III-V nanostructures with silicon electronic platform [8,18,30].
  • Research styleDubrovskii prefers analytical calculations to computers and tries to present theoretical models for complex growth behavior in a simple analytic form with a minimum number of physically transparent parameters.

    Current research interests

    Dubrovskii main areas are currently in modeling and shaping of sophisticated nanowire nanoheterostructures, nucleation theory in the nanoscale, physical chemistry of alloys and compounds, and analytic size distributions. He is working with experimentalists on design and functionalization of optoelectronic nanoheterostructures.

    Lecture courses and PhD studentsDubrovskii is lecturing in nucleation theory, epitaxy of nanostructures and growth modeling of nanowires. He has supervised 10 PhD students, 2 of them under European Marie Curie Initial Training Networks.

    Books and book chapters

    Articles[1] Dubrovskii . V. G. . Cirlin . G. E. . Soshnikov . I. P. . Tonkikh . A. A. . Sibirev . N. V. . Samsonenko . Yu. B. . Ustinov . V. M. . Diffusion-induced growth of GaAs nanowhiskers during molecular beam epitaxy: Theory and experiment . Physical Review B . American Physical Society (APS) . 71 . 20 . 2005-05-31 . 1098-0121 . 10.1103/physrevb.71.205325 . 205325. 2005PhRvB..71t5325D .
    [2] Glas . Frank . Harmand . Jean-Christophe . Patriarche . Gilles . Why Does Wurtzite Form in Nanowires of III-V Zinc Blende Semiconductors? . Physical Review Letters . 99 . 14 . 2007-10-05 . 0031-9007 . 10.1103/physrevlett.99.146101 . 146101. 17930689 . 0706.0846 . 2007PhRvL..99n6101G . 14209075 .
    [3] Dubrovskii . V. G. . Sibirev . N. V. . Growth thermodynamics of nanowires and its application to polytypism of zinc blende III-V nanowires . Physical Review B . American Physical Society (APS) . 77 . 3 . 2008-01-15 . 1098-0121 . 10.1103/physrevb.77.035414 . 035414. 2008PhRvB..77c5414D .
    [4] Dubrovskii . V. G. . Cirlin . G. E. . Sibirev . N. V. . Jabeen . F. . Harmand . J. C. . Werner . P. . New Mode of Vapor−Liquid−Solid Nanowire Growth . Nano Letters . American Chemical Society (ACS) . 11 . 3 . 2011-03-09 . 1530-6984 . 10.1021/nl104238d . 1247–1253. 21344916 . 2011NanoL..11.1247D .
    [5] Gil . Evelyne . Dubrovskii . Vladimir G. . Avit . Geoffrey . André . Yamina . Leroux . Christine . Lekhal . Kaddour . Grecenkov . Jurij . Trassoudaine . Agnès . Castelluci . Dominique . Monier . Guillaume . Ramdani . Reda M. . Robert-Goumet . Christine . Bideux . Luc . Harmand . Jean Christophe . Glas . Frank . 5. Record Pure Zincblende Phase in GaAs Nanowires down to 5 nm in Radius . Nano Letters . American Chemical Society (ACS) . 14 . 7 . 2014-06-03 . 1530-6984 . 10.1021/nl501239h . 3938–3944. 24873917 . 2014NanoL..14.3938G .
    [6] Tersoff . J. . Stable Self-Catalyzed Growth of III–V Nanowires . Nano Letters . American Chemical Society (ACS) . 15 . 10 . 2015-09-21 . 1530-6984 . 10.1021/acs.nanolett.5b02386 . 6609–6613. 26389697 . 2015NanoL..15.6609T .
    [7] Priante . G. . Ambrosini . S. . Dubrovskii . V. G. . Franciosi . A. . Rubini . S. . Stopping and Resuming at Will the Growth of GaAs Nanowires . Crystal Growth & Design . American Chemical Society (ACS) . 13 . 9 . 2013-08-16 . 1528-7483 . 10.1021/cg400701w . 3976–3984.
    [8] Dubrovskii . V. G. . Xu . T. . Álvarez . A. Díaz . Plissard . S. R. . Caroff . P. . Glas . F. . Grandidier . B. . Self-Equilibration of the Diameter of Ga-Catalyzed GaAs Nanowires . Nano Letters . American Chemical Society (ACS) . 15 . 8 . 2015-07-22 . 1530-6984 . 10.1021/acs.nanolett.5b02226 . 5580–5584. 26189571 . 2015NanoL..15.5580D .
    [9] Dubrovskii . Vladimir G. . Berdnikov . Yury . Schmidtbauer . Jan . Borg . Mattias . Storm . Kristian . Deppert . Knut . Johansson . Jonas . Length Distributions of Nanowires Growing by Surface Diffusion . Crystal Growth & Design . American Chemical Society (ACS) . 16 . 4 . 2016-03-21 . 1528-7483 . 10.1021/acs.cgd.5b01832 . 2167–2172.
    [10] Dubrovskii . V G . Sibirev . N V . Berdnikov . Y . Gomes . U P . Ercolani . D . Zannier . V . Sorba . L . Length distributions of Au-catalyzed and In-catalyzed InAs nanowires . Nanotechnology . IOP Publishing . 27 . 37 . 2016-08-08 . 0957-4484 . 10.1088/0957-4484/27/37/375602 . 375602. 27501469 . 2016Nanot..27K5602D . 41474044 .
    [11] Dubrovskii . Vladimir G. . Fully Analytical Description for the Composition of Ternary Vapor–Liquid–Solid Nanowires . Crystal Growth & Design . American Chemical Society (ACS) . 15 . 12 . 2015-11-19 . 1528-7483 . 10.1021/acs.cgd.5b00924 . 5738–5743.
    [12] Dubrovskii . V. G. . Sibirev . N. V. . Factors Influencing the Interfacial Abruptness in Axial III–V Nanowire Heterostructures . Crystal Growth & Design . American Chemical Society (ACS) . 16 . 4 . 2016-03-23 . 1528-7483 . 10.1021/acs.cgd.5b01613 . 2019–2023.
    [13] Gao . Qian . Dubrovskii . Vladimir G. . Caroff . Philippe . Wong-Leung . Jennifer . Li . Li . Guo . Yanan . Fu . Lan . Tan . Hark Hoe . Jagadish . Chennupati . Simultaneous Selective-Area and Vapor–Liquid–Solid Growth of InP Nanowire Arrays . Nano Letters . American Chemical Society (ACS) . 16 . 7 . 2016-06-06 . 1530-6984 . 10.1021/acs.nanolett.6b01461 . 4361–4367. 27253040 . 2016NanoL..16.4361G .
    [14] Dubrovskii . Vladimir G. . Consonni . Vincent . Trampert . Achim . Geelhaar . Lutz . Riechert . Henning . Scaling thermodynamic model for the self-induced nucleation of GaN nanowires . Physical Review B . American Physical Society (APS) . 85 . 16 . 2012-04-23 . 1098-0121 . 10.1103/physrevb.85.165317 . 165317. 2012PhRvB..85p5317D .
    [15] Dubrovskii . V. G. . Fluctuation-induced spreading of size distribution in condensation kinetics . The Journal of Chemical Physics . AIP Publishing . 131 . 16 . 2009-10-28 . 0021-9606 . 10.1063/1.3254384 . 164514. 19894963 . 2009JChPh.131p4514D .
    [16] Dubrovskii . V. G. . Nazarenko . M. V. . Nucleation theory beyond the deterministic limit. I. The nucleation stage . The Journal of Chemical Physics . AIP Publishing . 132 . 11 . 2010-03-21 . 0021-9606 . 10.1063/1.3354118 . 114507. 20331305 . 2010JChPh.132k4507D .
    [17] Dubrovskii . V. G. . Kazansky . M. A. . Nazarenko . M. V. . Adzhemyan . L. T. . Numerical analysis of Ostwald ripening in two-dimensional systems . The Journal of Chemical Physics . AIP Publishing . 134 . 9 . 2011-03-07 . 0021-9606 . 10.1063/1.3556658 . 094507. 21384985 . 2011JChPh.134i4507D .
    [18] Dubrovskii . V. G. . Sibirev . N. V. . Zhang . X. . Suris . R. A. . Stress-Driven Nucleation of Three-Dimensional Crystal Islands: From Quantum Dots to Nanoneedles . Crystal Growth & Design . American Chemical Society (ACS) . 10 . 9 . 2010 . 1528-7483 . 10.1021/cg100495b . 3949–3955.
    [19] Dubrovsky . V. G. . On an exact solution of master equations for the model of reversible growth . Theoretical and Mathematical Physics . Springer Science and Business Media LLC . 108 . 2 . 1996 . 0040-5779 . 10.1007/bf02070679 . 1110–1118. 1996TMP...108.1110D . 123369783 .
    [20] Dubrovskii . V. G. . Sibirev . N. V. . Analytic scaling function for island-size distributions . Physical Review E . American Physical Society (APS) . 91 . 4 . 2015-04-29 . 1539-3755 . 10.1103/physreve.91.042408 . 042408. 25974509 . 2015PhRvE..91d2408D .
    [21] Vicsek . Tamás . Family . Fereydoon . Dynamic Scaling for Aggregation of Clusters . Physical Review Letters . American Physical Society (APS) . 52 . 19 . 1984-05-07 . 0031-9007 . 10.1103/physrevlett.52.1669 . 1669–1672. 1984PhRvL..52.1669V .
    [22] Dubrovskii . Vladimir G. . Sibirev . Nickolai V. . Growth rate of a crystal facet of arbitrary size and growth kinetics of vertical nanowires . Physical Review E . American Physical Society (APS) . 70 . 3 . 2004-09-15 . 1539-3755 . 10.1103/physreve.70.031604 . 031604. 15524531 . 2004PhRvE..70c1604D .
    [23] Dubrovskii . V.G. . Grecenkov . J. . Zeldovich Nucleation Rate, Self-Consistency Renormalization, and Crystal Phase of Au-Catalyzed GaAs Nanowires . Crystal Growth & Design . American Chemical Society (ACS) . 15 . 1 . 2014-12-02 . 1528-7483 . 10.1021/cg5014208 . 340–347.
    [24] Dubrovskii . V. G. . Xu . T. . Lambert . Y. . Nys . J.-P. . Grandidier . B. . Stiévenard . D. . Chen . W. . Pareige . P. . Narrowing the Length Distribution of Ge Nanowires . Physical Review Letters . American Physical Society (APS) . 108 . 10 . 2012-03-05 . 0031-9007 . 10.1103/physrevlett.108.105501 . 105501. 22463421 . 2012PhRvL.108j5501D .
    [25] Dubrovskii . V. G. . Self-regulated pulsed nucleation in catalyzed nanowire growth . Physical Review B . American Physical Society (APS) . 87 . 19 . 2013-05-14 . 1098-0121 . 10.1103/physrevb.87.195426 . 195426. 2013PhRvB..87s5426D .
    [26] Dubrovskii . V. G. . Kinetic narrowing of size distribution . Physical Review B . American Physical Society (APS) . 93 . 17 . 2016-05-23 . 2469-9950 . 10.1103/physrevb.93.174203 . 174203. 2016PhRvB..93q4203D .
    [27] F. Glas and V. G. Dubrovskii, Phys. Rev. B, submitted (2017).
    [28] Glas . Frank . Harmand . Jean-Christophe . Patriarche . Gilles . Nucleation Antibunching in Catalyst-Assisted Nanowire Growth . Physical Review Letters . American Physical Society (APS) . 104 . 13 . 2010-03-31 . 0031-9007 . 10.1103/physrevlett.104.135501 . 135501. 20481891 . 2010PhRvL.104m5501G .
    [29] Zhang . Xu . Dubrovskii . Vladimir G. . Sibirev . Nickolay V. . Ren . Xiaomin . Analytical Study of Elastic Relaxation and Plastic Deformation in Nanostructures on Lattice Mismatched Substrates . Crystal Growth & Design . American Chemical Society (ACS) . 11 . 12 . 2011-12-07 . 1528-7483 . 10.1021/cg201029x . 5441–5448.
    [30] Ng . Kar Wei . Ko . Wai Son . Tran . Thai-Truong D. . Chen . Roger . Nazarenko . Maxim V. . Lu . Fanglu . Dubrovskii . Vladimir G. . Kamp . Martin . Forchel . Alfred . Chang-Hasnain . Connie J. . Unconventional Growth Mechanism for Monolithic Integration of III–V on Silicon . ACS Nano . American Chemical Society (ACS) . 7 . 1 . 2012-12-20 . 1936-0851 . 10.1021/nn3028166 . 100–107. 23240995 .

    Appointments and memberships

    Publication record

    Dubrovskii has authored and co-authored more than 600 research papers in leading technical journals and conferences, with more than 250 journal papers indexed by WoS. His Hirsh-index is 40 (WoS).

    Honors

    Notes and References

    1. Web site: Дубровский Владимир Германович | Кафедры физики СПб АУ РАН.
    2. Web site: The page is inaccessible temporarily.
    3. Web site: International Research Laboratory of Physics of Epitaxial Nanostructures.
    4. Web site: May 29 - June 2, 2017 - Lund, Sweden | Nanowire Week.