Emmanuel Rashba | |
---|---|
Ukrainian: Еммануїл Йосипович Рашба Russian: Эммануил Иосифович Рашба | |
Born | |
Nationality | American |
Citizenship | US |
Alma mater | Taras Shevchenko National University of Kyiv, Physical Department |
Known for | Rashba effect EDSR Giant oscillator strength Non-Euclidean surface growth |
Scientific career | |
Fields | Condensed matter physics, spintronics, nanoscience |
Institutions | Institute of Physics (Kyiv), Institute of Semiconductors (Kyiv), Landau Institute for Theoretical Physics (Moscow), University of Utah (Salt Lake City), University at Buffalo, SUNY Harvard University (Cambridge, Massachusetts) |
Emmanuel I. Rashba (born October 30, 1927, Kyiv) is a Soviet-American theoretical physicist of Jewish origin who worked in Ukraine, Russia and in the United States. Rashba is known for his contributions to different areas of condensed matter physics and spintronics, especially the Rashba effect in spin physics, and also for the prediction of electric dipole spin resonance (EDSR), [1] that was widely investigated [2] and became a regular tool for operating electron spins in nanostructures, phase transitions in spin-orbit coupled systems driven by change of the Fermi surface topology, [3] Giant oscillator strength of impurity excitons, [4] and coexistence of free and self-trapped excitons. [5] The principal subject of spintronics is all-electric operation of electron spins, and EDSR was the first phenomenon predicted and experimentally observed in this field.
Born in Kyiv, Ukraine, Rashba survived the Nazi invasion during the Second World War by fleeing with his family to Kazan where he started studying physics at the Kazan University. His father Iosif (Joseph) Rashba was a prominent defence lawyer, a widely educated humanitarian, and his mother Rosalia was a teacher of English. [6] After returning to Kyiv he graduated, with high honors, from the Physics Department of Kyiv University in 1949. His Instructors were Alexander Davydov, Solomon Pekar and Kirill Tolpygo.
Rashba' graduation from the university fell onto the last years of Stalin's reign darkened by extreme national chauvinism. As a result, he had to change temporary jobs five times during the five following years. During this time he initiated, as applied to dams, theory of gravitational stresses in growing elastic bodies [7] (non-Euclidean grows, in current terminology), and also developed theory of exciton-phonon coupling in molecular crystals. In 1954 Rashba was accepted to the Semiconductor Department of the Institute of Physics of the National Academy of Sciences of Ukraine where he initially worked on the theory of transistors but earned his PhD degree in 1956 on his work on exciton-phonon coupling (including prediction of coexistence of free and self-trapped excitons, discovered experimentally two decades later on, based on the concept of self-trapping barrier for excitons essential for current work on Sun energy conversion). When the Institute for Semiconductors of the same Academy was established in 1960, Rashba headed there the Department for Theory of Semiconductor Devices. He earned his Doctor of Sciences degree from the A.F. Ioffe Institute in Leningrad in 1963 for his work on spin-orbit coupling in semiconductors and exciton spectroscopy of molecular crystals (deducing energy spectra of excitons in pure crystals from optical spectra of mixed crystals, in collaboration with Vladimir Broude). In collaboration with Solomon Pekar, Rashba introduced a mechanism of spin-orbit interaction in magnetic media originating from the coupling of electron spin to microscopically inhomogeneous magnetic field of magnetic background. [8]
In 1966, after the Institute of Theoretical Physics of the Academy of Sciences of USSR (currently the Landau Institute for Theoretical Physics) was established in Chernogolovka (Moscow district), Rashba moved there and served as the head of the Theory of Semiconductors Division and afterwards as a principal scientist until 1997. During 1967-1991, Rashba also served as a professor of physics at the Moscow Institute of Physics and Technology (MIPT).
In 1991 Rashba moved to the United States, where he worked as a research scholar at the University of Utah (1992–1999), SUNY at Buffalo (2001–2004), and Harvard University (2004–2015). He was also associated with Massachusetts Institute of Technology (MIT, 2000–2004), served as an adjunct professor at Dartmouth College (2000–2003) and as a Rutherford Professor at the Loughborough University (2007–2010). During this period Rashba worked mostly on spintronics and physics of nanosystems. After Rashba's severe neurological disease (1997) his work was facilitated by his wife Erna and the family of his daughter.
For about 15 years Rashba served as a member of the editorial boards of the journals JETP Letters and Journal of Luminescence .
Rashba is a Fellow of the American Physical Society. Among his recognitions are 1966 National Prize of the USSR and the International Conference on Luminescence ICL'99 Prize for his work on optical spectroscopy, Ioffe (1987, USSR), Pekar (2007, Ukraine), Doctor of Honoris Causa of Bogolyubov Institute for Theoretical Physics (2022, Ukraine), and Oliver E. Buckley (2022, US) Prizes for his work on spin-related phenomena, and 2005 Sir Nevill Mott (UK) and 2005 Arkady Aronov (Israel) Lectureships.
Rashba's name became a part of a number of technical terms such as Rashba Hamiltonian, giant Rashba systems, Rashba physics, etc., which are parts of the titles of about 4000 scientific papers. According to Google Scholar, paper Ref. [1] is the most cited and Ref. [9] is the second most cited of the papers published in these journals, respectively.
An electron and an electron hole that are attracted to each other by the Coulomb force can form a bound state called an exciton. It is an electrically neutral quasiparticle that exists mainly in condensed matter, including insulators, semiconductors, some metals, but also in certain atoms, molecules and liquids. The exciton is regarded as an elementary excitation that can transport energy without transporting net electric charge.
Spintronics, also known as spin electronics, is the study of the intrinsic spin of the electron and its associated magnetic moment, in addition to its fundamental electronic charge, in solid-state devices. The field of spintronics concerns spin-charge coupling in metallic systems; the analogous effects in insulators fall into the field of multiferroics.
In physics, polaritons are quasiparticles resulting from strong coupling of electromagnetic waves with an electric or magnetic dipole-carrying excitation. They are an expression of the common quantum phenomenon known as level repulsion, also known as the avoided crossing principle. Polaritons describe the crossing of the dispersion of light with any interacting resonance. To this extent polaritons can also be thought of as the new normal modes of a given material or structure arising from the strong coupling of the bare modes, which are the photon and the dipolar oscillation. The polariton is a bosonic quasiparticle, and should not be confused with the polaron, which is an electron plus an attached phonon cloud.
A polaron is a quasiparticle used in condensed matter physics to understand the interactions between electrons and atoms in a solid material. The polaron concept was proposed by Lev Landau in 1933 and Solomon Pekar in 1946 to describe an electron moving in a dielectric crystal where the atoms displace from their equilibrium positions to effectively screen the charge of an electron, known as a phonon cloud. This lowers the electron mobility and increases the electron's effective mass.
In particle physics, spin polarization is the degree to which the spin, i.e., the intrinsic angular momentum of elementary particles, is aligned with a given direction. This property may pertain to the spin, hence to the magnetic moment, of conduction electrons in ferromagnetic metals, such as iron, giving rise to spin-polarized currents. It may refer to (static) spin waves, preferential correlation of spin orientation with ordered lattices.
The spin Hall effect (SHE) is a transport phenomenon predicted by Russian physicists Mikhail I. Dyakonov and Vladimir I. Perel in 1971. It consists of the appearance of spin accumulation on the lateral surfaces of an electric current-carrying sample, the signs of the spin directions being opposite on the opposing boundaries. In a cylindrical wire, the current-induced surface spins will wind around the wire. When the current direction is reversed, the directions of spin orientation is also reversed.
Anatoly Ivanovich Larkin was a Russian theoretical physicist, universally recognised as a leader in theory of condensed matter, and who was also a celebrated teacher of several generations of theorists.
The Institute of Physics (IOP) of the National Academy of Sciences of Ukraine founded in 1926 is the oldest research institution of physical science within the academy. Being on the path of both infrastructure development and research diversification for more than 80 years, the institute has eventually originated five more specialized research institutions.
The Rashba effect, also called Bychkov–Rashba effect, is a momentum-dependent splitting of spin bands in bulk crystals and low-dimensional condensed matter systems similar to the splitting of particles and anti-particles in the Dirac Hamiltonian. The splitting is a combined effect of spin–orbit interaction and asymmetry of the crystal potential, in particular in the direction perpendicular to the two-dimensional plane. This effect is named in honour of Emmanuel Rashba, who discovered it with Valentin I. Sheka in 1959 for three-dimensional systems and afterward with Yurii A. Bychkov in 1984 for two-dimensional systems.
Kirill Borisovich Tolpygo was a Soviet physicist and a corresponding member of the National Academy of Sciences of Ukraine. He was recognized for his works on condensed matter theory; the theory of phonon spectra in crystals; electronic structure and defects in insulators and semiconductors; and biophysics. He created the Department of Theoretical Physics and the Department of Biophysics at Donetsk National University. Tolpygo was a teacher, mentor and scientific adviser to graduate students. Tolpygo was awarded the Order of the Great Patriotic War.
Solomon Isakovych Pekar was a Soviet theoretical physicist, born in Kyiv, Ukraine. He was a full Member of the Ukrainian Academy of Sciences and is known for his fundamental contributions to condensed matter physics, especially for introducing and advancing the concept of polaron as a charge carrier in solids.
Electric dipole spin resonance (EDSR) is a method to control the magnetic moments inside a material using quantum mechanical effects like the spin–orbit interaction. Mainly, EDSR allows to flip the orientation of the magnetic moments through the use of electromagnetic radiation at resonant frequencies. EDSR was first proposed by Emmanuel Rashba.
Vsevolod Feliksovich Gantmakher, was a prominent Russian experimental physicist of Jewish origin, was born in Moscow as son of Felix Gantmacher, a prominent mathematician. He was a full Member of the Russian Academy of Sciences and is known for his fundamental contributions to condensed matter physics especially for the Gantmakher effect and Gantmakher–Kaner oscillations.
Vadim Evgenievich Lashkaryov, a prominent Soviet experimental physicist, was born in Kyiv, to a family of a lawyer. He was an Academician of the National Academy of Sciences of Ukraine and is known for his fundamental contributions to physics of semiconductors.
Antonina Fedorivna Prykhotko, was a Soviet and Ukrainian experimental physicist. She was an Academician of the National Academy of Sciences of Ukraine and is known for her fundamental contributions to the condensed matter spectroscopy.
Giant oscillator strength is inherent in excitons that are weakly bound to impurities or defects in crystals.
Vladimir Lvovich Broude, was a Soviet and Russian experimental physicist of Jewish descent. His father was a Professor of biochemistry and his mother was a medical doctor. His elder brother Yevgeny was conscripted soon after beginning of the Nazi invasion in June 1941 and lost his life.
Gregory Evgenievich (Ezekielevich) Pikus was a Soviet theoretical physicist whose contributions strongly influenced developing physics of semiconductors. Among his most fundamental contributions are development of the method of invariants in band theory of solids, the Bir-Aronov-Pikus mechanism of spin relaxation of electrons, prediction of the circular photogalvanic effect, and theory of weak localization in noncentrosymmetric structures. His three monographs reflect the focus points of the theory of semiconductors during the second half of the 20th century from transistors to band theory to properties to artificial nanostructures.
The Dresselhaus effect is a phenomenon in solid-state physics in which spin–orbit interaction causes energy bands to split. It is usually present in crystal systems lacking inversion symmetry. The effect is named after Gene Dresselhaus, who discovered this splitting in 1955.
Gene Frederick Dresselhaus was an American condensed matter physicist. He is known as a pioneer of spintronics and for his 1955 discovery of the eponymous Dresselhaus effect.