Carlos Stroud | |
---|---|
Born | Owensboro, KY | July 9, 1942
Nationality | American |
Alma mater | Centre College Washington University in St. Louis |
Known for | Single-mode tunable dye lasers Hyperfine structure of atomic sodium Coherent population trapping Electron wave packets Rydberg atomic states Classical limit of quantum mechanics Wave packet revivals and fractional revivals |
Scientific career | |
Fields | Theoretical and experimental quantum optics |
Institutions | University of Rochester |
Thesis | Quantum and Semiclassical Radiation Theory |
Doctoral advisor | Edwin Thompson Jaynes |
Carlos Ray Stroud, Jr. (born July 9, 1942, in Owensboro, KY) is an American physicist and educator. Working in the field of quantum optics, Stroud has carried out theoretical and experimental studies in most areas of the field from its beginnings in the late 1960s, studying the fundamentals of the quantum mechanics of atoms and light and their interaction. He has authored over 140 peer-reviewed papers and edited seven books. He is a fellow of the American Physical Society and the Optical Society of America, as well as a Distinguished Traveling Lecturer of the Division of Laser Science of the American Physical Society. In this latter position he travels to smaller colleges giving colloquia and public lectures.
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Carlos Stroud grew up in Kentucky and graduated from Centre College in 1963, with degrees in mathematics and physics. In 1969 he earned a Ph.D. in physics from Washington University in St. Louis, under the mentorship of E. T. Jaynes, with the thesis titled Quantum and Semiclassical Radiation Theory. In 1969 Stroud joined the faculty of The Institute of Optics at the University of Rochester. Over his 50-year career at the University of Rochester, Professor Stroud taught undergraduate and graduate courses in general and quantum physics and optics, while conducting groundbreaking research in several areas of quantum optics, graduating 30 Ph.D.s. He was named professor of optics in 1984 and professor of physics and astronomy in 1991.
In 2004, Stroud collected and edited A Jewel in the Crown: Essays in Honor of the 75th Anniversary of the Institute of Optics, a compilation of 75 essays on the history of the University of Rochester's Institute of Optics (19 of the essays were authored or co-authored by Stroud himself). In 2019, Stroud and Gina Kern co-edited A Jewel in the Crown II: Essays in Honor of the 90th Anniversary of the Institute of Optics. For his contributions in gathering and documenting the Institute of Optics' history, on his retirement on July 1, 2019, Stroud was named professor emeritus of optics and optics historian.
Soon after joining the faculty of the Institute of Optics at the University of Rochester, Stroud collaborated with Michael Hercher, developing the first single-mode tunable dye laser and using it to study its interaction with sodium atoms in an atomic beam. This work produced a series of groundbreaking experiments, including the study of the hyperfine structure of the D-lines, the isolation of a closed two-level resonance, power broadening, and resonance fluorescence in this system. This first observation of the Mollow sidebands in resonance fluorescence was fundamental to understanding of the nature of quantum correlations in a coherently pumped two-level system. [1] Groups at MIT and the Max Planck Institute in Garching were also racing to be first to observe this spectrum, and did indeed confirm the initial results.
These experimental observations were soon followed by two-laser studies of three-level quantum systems. The first cw study of the Autler–Townes effect, and the first experimental study of the extremely sharp resonance associated with coherent population trapping were made. [2] This observation led to the later development of electromagnetically induced transparency by Harris and others, [3] as well as Stimulated Raman Adiabatic Passage (STIRAP). [4] These pioneering experimental studies were accompanied by theoretical papers providing the underpinning concepts and models, and introducing much of the standard terminology of the fields, including “lambda”, “v”, and “cascade” for describing three-level configurations, “coherent population trapping” as well as introducing, with Cohen-Tannoudji, the dressed-state basis for resonance fluorescence and Autler-Townes studies.
In a series of some 50 papers from the early 1980s well into the 2000s, Stroud’s group studied the production and evolution of spatially localized electron wave packets made up of superpositions of Rydberg atomic states. These states are quite classical in their behavior, travelling several orbits around the nucleus as effectively Keplerian systems, but after a few orbits the packets demonstrate their quantum nature by undergoing decays, revivals and fractional revivals. In a fractional revival the initial wave packet splits into a set of smaller wave packets moving in the classical orbit. Parker and Stroud [5] were the first to predict these fractional revivals, which were then observed by Yeazell and Stroud. [6] This whole series of studies showed how a quantum system could be manipulated in a very controlled fashion to alternatively show classical and quantum features during a complex time evolution. A single electron could be made to interfere with itself to exhibit interference fringes, or to move like a classical localized particle. By the application of Stark fields and THz half-cycle pulses, the electrons could even be made to oscillate, while localized along a linear orbit some 1000 Angstroms in length.
Antihydrogen is the antimatter counterpart of hydrogen. Whereas the common hydrogen atom is composed of an electron and proton, the antihydrogen atom is made up of a positron and antiproton. Scientists hope that studying antihydrogen may shed light on the question of why there is more matter than antimatter in the observable universe, known as the baryon asymmetry problem. Antihydrogen is produced artificially in particle accelerators.
Ionization is the process by which an atom or a molecule acquires a negative or positive charge by gaining or losing electrons, often in conjunction with other chemical changes. The resulting electrically charged atom or molecule is called an ion. Ionization can result from the loss of an electron after collisions with subatomic particles, collisions with other atoms, molecules, electrons, positrons, protons, antiprotons and ions, or through the interaction with electromagnetic radiation. Heterolytic bond cleavage and heterolytic substitution reactions can result in the formation of ion pairs. Ionization can occur through radioactive decay by the internal conversion process, in which an excited nucleus transfers its energy to one of the inner-shell electrons causing it to be ejected.
Matter waves are a central part of the theory of quantum mechanics, being half of wave–particle duality. At all scales where measurements have been practical, matter exhibits wave-like behavior. For example, a beam of electrons can be diffracted just like a beam of light or a water wave.
Electromagnetically induced transparency (EIT) is a coherent optical nonlinearity which renders a medium transparent within a narrow spectral range around an absorption line. Extreme dispersion is also created within this transparency "window" which leads to "slow light", described below. It is in essence a quantum interference effect that permits the propagation of light through an otherwise opaque atomic medium.
A Rydberg atom is an excited atom with one or more electrons that have a very high principal quantum number, n. The higher the value of n, the farther the electron is from the nucleus, on average. Rydberg atoms have a number of peculiar properties including an exaggerated response to electric and magnetic fields, long decay periods and electron wavefunctions that approximate, under some conditions, classical orbits of electrons about the nuclei. The core electrons shield the outer electron from the electric field of the nucleus such that, from a distance, the electric potential looks identical to that experienced by the electron in a hydrogen atom.
An atom interferometer uses the wave-like nature of atoms in order to produce interference. In atom interferometers, the roles of matter and light are reversed compared to the laser based interferometers, i.e. the beam splitter and mirrors are lasers while the source emits matter waves rather than light. Atom interferometers measure the difference in phase between atomic matter waves along different paths. Matter waves are controlled an manipulated using systems of lasers. Atom interferometers have been used in tests of fundamental physics, including measurements of the gravitational constant, the fine-structure constant, and universality of free fall. Applied uses of atom interferometers include accelerometers, rotation sensors, and gravity gradiometers.
Atom optics "refers to techniques to manipulate the trajectories and exploit the wave properties of neutral atoms". Typical experiments employ beams of cold, slowly moving neutral atoms, as a special case of a particle beam. Like an optical beam, the atomic beam may exhibit diffraction and interference, and can be focused with a Fresnel zone plate or a concave atomic mirror.
A charge density wave (CDW) is an ordered quantum fluid of electrons in a linear chain compound or layered crystal. The electrons within a CDW form a standing wave pattern and sometimes collectively carry an electric current. The electrons in such a CDW, like those in a superconductor, can flow through a linear chain compound en masse, in a highly correlated fashion. Unlike a superconductor, however, the electric CDW current often flows in a jerky fashion, much like water dripping from a faucet due to its electrostatic properties. In a CDW, the combined effects of pinning and electrostatic interactions likely play critical roles in the CDW current's jerky behavior, as discussed in sections 4 & 5 below.
A composite fermion is the topological bound state of an electron and an even number of quantized vortices, sometimes visually pictured as the bound state of an electron and, attached, an even number of magnetic flux quanta. Composite fermions were originally envisioned in the context of the fractional quantum Hall effect, but subsequently took on a life of their own, exhibiting many other consequences and phenomena.
A trojan wave packet is a wave packet that is nonstationary and nonspreading. It is part of an artificially created system that consists of a nucleus and one or more electron wave packets, and that is highly excited under a continuous electromagnetic field. Its discovery as one of significant contributions to the Quantum Theory was awarded the 2022 Wigner Medal for Iwo Bialynicki-Birula
A trion is a bound state of three charged particles. A negatively charged trion in crystals consists of two electrons and one hole, while a positively charged trion consists of two holes and one electron. The binding energy of a trion is largely determined by the exchange interaction between the two electrons (holes). The ground state of a negatively charged trion is a singlet. The triplet state is unbound in the absence of an additional potential or sufficiently strong magnetic field.
Robert William Boyd is an American physicist noted for his work in optical physics and especially in nonlinear optics. He is currently the Canada Excellence Research Chair Laureate in Quantum Nonlinear Optics based at the University of Ottawa, professor of physics cross-appointed to the school of electrical engineering and computer science at the University of Ottawa, and professor of optics and professor of physics at the University of Rochester.
Double ionization is a process of formation of doubly charged ions when laser radiation is exerted on neutral atoms or molecules. Double ionization is usually less probable than single-electron ionization. Two types of double ionization are distinguished: sequential and non-sequential.
In quantum mechanics, quantum scarring is a phenomenon where the eigenstates of a classically chaotic quantum system have enhanced probability density around the paths of unstable classical periodic orbits. The instability of the periodic orbit is a decisive point that differentiates quantum scars from the more trivial observation that the probability density is enhanced in the neighborhood of stable periodic orbits. The latter can be understood as a purely classical phenomenon, a manifestation of the Bohr correspondence principle, whereas in the former, quantum interference is essential. As such, scarring is both a visual example of quantum-classical correspondence, and simultaneously an example of a (local) quantum suppression of chaos.
Terahertz spectroscopy detects and controls properties of matter with electromagnetic fields that are in the frequency range between a few hundred gigahertz and several terahertz. In many-body systems, several of the relevant states have an energy difference that matches with the energy of a THz photon. Therefore, THz spectroscopy provides a particularly powerful method in resolving and controlling individual transitions between different many-body states. By doing this, one gains new insights about many-body quantum kinetics and how that can be utilized in developing new technologies that are optimized up to the elementary quantum level.
Quantum microscopy allows microscopic properties of matter and quantum particles to be measured and imaged. Various types of microscopy use quantum principles. The first microscope to do so was the scanning tunneling microscope, which paved the way for development of the photoionization microscope and the quantum entanglement microscope.
Kenneth John Button was a solid-state and plasma physicist. He was the editor-in-chief of the International Journal of Infrared and Millimeter Waves from its inception in 1980 until his resignation in 2004.
A Rydberg polaron is an exotic quasiparticle, created at low temperatures, in which a very large atom contains other ordinary atoms in the space between the nucleus and the electrons. For the formation of this atom, scientists had to combine two fields of atomic physics: Bose–Einstein condensates and Rydberg atoms. Rydberg atoms are formed by exciting a single atom into a high-energy state, in which the electron is very far from the nucleus. Bose–Einstein condensates are a state of matter that is produced at temperatures close to absolute zero.
An electron-on-helium qubit is a quantum bit for which the orthonormal basis states |0⟩ and |1⟩ are defined by quantized motional states or alternatively the spin states of an electron trapped above the surface of liquid helium. The electron-on-helium qubit was proposed as the basic element for building quantum computers with electrons on helium by Platzman and Dykman in 1999.
William P. Halperin is a Canadian-American physicist, academic, and researcher. He is the Orrington Lunt Professor of Physics at Northwestern University.