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Research Interests

Dr. Marilyn F. Bishop
Theoretical Condensed Matter Physics, Theoretical Biophysics
In the area of condensed matter physics, the two major thrusts have been (1) theoretical studies of charge density waves and spin density waves in simple metals and (2) the theory of superconductivity. The importance of understanding the properties of simple metals extends well beyond the explaination of a few phenomena. Different theoretical treatments of electron-electron interactions of exchange and correlation in an electron gas will lead to different ground states, and the choice of the ground state one uses can lead to various predictions of optical and transport properties of a simple metal. This implies that the simple metals, especially the alkali metals, are a testing ground for theories of electron gas interactions. Comparison of theory with a large number of experiments shows that the correct ground state of simple metals must be that of a charge density wave. Until one can explain the properties of the alkali metals, the predictions for more complicated systems will also be in question. In fact, the understanding of the electronic interactions in superconductors must rely on some of the same principles as found in simple metals.

The work on simple metals has included a theory of the residual resistivity anisotropy determined in potassium by induced torque measurements, a theory of electron-phason scattering and an explaination of the low temperature resistivity of potassium below 1.3 K, including variability from sample to sample, localization effects in thin potassium wire, effects of charge density waves on the x-ray band spectra of alkali metals, and the calculation of the Bloch-Grüneisen functions by the use of series expansions. Current and future work include Hartree-Fock calculations of spin density waves in one and three dimensional systems, including the study of spiral and canted spiral spin density wave states. In the study of superconductivity, my work has involved a study of the phonon-mediated electron-electron interaction, which is integral to the BCS theory of superconductivity and is important in the theory of bipolaronic superconductors, and a theory of the proximity-induced superconducting transition temperature.

The research in biophysics involves the theoretical study of the kinetics of polymerization, light scattering, and optical properties of biological polymers. Kinetic theories, which include the nucleation and growth of polymers, have been applied to sickle hemoglobin, actin, and collagen. Actin, a fibrous tissue in muscle and an important component in the structure of cells, undergoes a polymerization that is complicated by the hydrolysis of ATP to ADP during the polymerization process. Sickle hemoglobin, which is a mutation of normal hemoglobin but transports oxygen as does normal hemoglobin, polymerizes only when deoxygenated, which occurs when delivering oxygen in the capillaries. Polymerization proceeds through a double nucleation process in which nuclei form from a solution of hemoglobin molecules (monomers) and once polymers are formed, nuclei are formed on the surfaces of existing polymers. The work on light scattering and optical properties of polymers focusses on sickle hemoglobin but could equally apply to any system in which the polymers are rigid straight fibers. These include actin, tubulin, intermediate filaments, myosin, collagen, crystallin, fibrin, and amyloid. Most formulations of light scattering from particles assume that those particles are dilute, i.e. well separated compared with the wavelength of light. This work is developing a theoretical formulation whose validity will range from the dilute to dense concentrations of polymers. This is especially important in the study of the sickle hemoglobin because the most physiologically significant regime ranges from intermediate to high concentration. In sickle hemoglobin, polymers are known to form in spherulitic arrays known as domains. Recent studies involve calculations of the expected light scattering from these domains as compared to scattering form individual polymers, in order to determine the processes involved in the growth and alignment of polymers in the formation of domains.

Marilyn F. Bishop and Frank A. Ferrone, "Kinetics of Nucleation-Controlled Polymerization", Biophys. J. 46, 631-644 (1984).

Marilyn F. Bishop, "Calculations of Scattered Light from Rigid Polymers by Shifrin and Rayleigh- Debye Approximations", Biophys. J. 56, 911-925 (1989).

Mary Eileen Farrell, Marilyn F. Bishop, "Theory of the Proximity-Induced Superconducting Transition Temperature", Phys. Rev. B 40, 10786-10795 (1989).

Mary Eileen Farrell, Marilyn F. Bishop, N. Kumar, and W.E. Lawrence, "Theory of the Effects of the Destruction of Localization by Inelastic Scattering in the Resistivity of Pure Thin Potassium Wires", Phys. Rev. B 42, 3260-3270 (1990).

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