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About Ulrich D. Jentschura

The main subject of Dr. Jentschura’s research group is to investigate fundamental physics questions in the low-energy domain, using a combination of computational physics methods and field-theoretical tools. The importance of atomic physics theory and experiment for the study of fundamental field-theoretical questions should not be underestimated. The most accurately known physical constant today, the Rydberg constant, has been determined to 12 significant decimals using a combination of highly accurate atomic theory and experimental data. Laboratory-based limits to the variation of fundamental constants with time have been derived on the basis of high-precision experiments. Rather sophisticated field-theoretical and numerical methods have to be employed in order to reach this accuracy. The subject has attracted considerable renewed interested because of an observed discrepancy of theory and experiment for the Lamb shift transition is muonic hydrogen.

In addition, the group studies laser-physics related questions in the high-energy domain. The Furry picture, which was originally developed for the Dirac-Coulomb problem (electrons bound in a strong Coulomb field), needs to be generalized to a modified Furry picture, for electrons moving in a strong time- and space-dependent laser field (Dirac-Volkov propagator). These investigations have topical importance because of the ongoing construction of high-power laser laboratories all around the World.

The group has also been studying anharmonic oscillators and their physical properties. These fundamental quantum mechanical Hamiltonians give rise to manifestly divergent perturbation series, and the energy of a bound quantum state in an anharmonic potential cannot be described by a convergent perturbation series. The large-order growth of perturbative coefficients is described by so-called Bender-Wu formulas. It has been possible to generalize the Bender-Wu formulas from even anharmonic oscillators to odd anharmonic oscillators, and to supplement these studies by field-theoretical methods. Furthermore, the so-called Bender-Wu cuts of the resonance energies of odd anharmonic oscillators on the second sheet of the Riemann surface of the coupling parameter have been identified for odd anharmonic oscillators.

These activities are complemented by studies on the renormalization-group flow of theories with periodic self-interactions in two dimensions, where the so-called sine-Gordon model undergoes a Kosterlitz-Thouless transition. Recent projects include the generalization of the path-integral analysis of the O(N) anharmonic oscillators to D spatial dimensions, which is equivalent to a D-dimensional statistical field theory undergoing a phase transition.

A common and unifying theme of the investigations is the use of modern computers. A couple of algorithms have been developed which have found useful applications beyond their originally intended realm of application. These include the so-called combined nonlinear-condensation transformation which was published in 1999. It is intended to accelerate the convergence of slowly convergent series with nonalternating terms, which constitutes a hard problem in numerical analysis. Traditional one-step acceleration methods like Pade-approximants fail because of excessive numerical cancellations in higher orders.  

Positions

2015 - Present Professor, Missouri University of Science and Technology Physics
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2013 - 2015 Associate Professor, Missouri University of Science and Technology Physics
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2009 - 2013 Assistant Professor, Missouri University of Science and Technology Physics
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Disciplines



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Honors and Awards

  • Georg-Helm Prize of the Technical University of Dresden (2000)
  • Habilitation (University of Dresden, 2003)
  • Heisenberg Stipend (2005)
  • Outstanding Referee of the American Physical Society (2010)
  • Faculty Excellence Award, Missouri University of Science and Technology, 2011 and 2013.
  • Fellow of the American Physical Society, 2013.

Education

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1999 Ph.D., University of Dresden
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Contact Information

119 Physics Building
Missouri University of Science and Technology
Rolla, MO 65409-0640

Phone: (573) 341-6221
Fax: (573) 341-4715

Email:


Research Works (241)