Institute for Mathematical Stochastics

Publikationen: PD Dr. Aspelmeier

  • Laitenberger, O., Aspelmeier, T., Staudt, T., Geisler, C., Munk, A., Egner, A. (2023).
    Towards Unbiased Fluorophore Counting in Superresolution Fluorescence Microscopy. Nanomaterials, 13(3), 459 Submitted.
  • Schmidt-Hieber, J., Schneider, LF., Staudt, T., Krajina, A., Aspelmeier, T., Munk, A. (2021).
    Posterior analysis of n in the binomial (n,p) problem with both parameters unknown -- with applications to quantitative nanoscopy. arXiv:1809.02443 The Annals of Statistics, 49(6), 3534-3558.
  • Frahm, L., Keller-Findeisen, K., Alt, P., Schnorrenberg, S., del Alamo Ruiz, M., Aspelmeier, T., Munk, A., Jakobs, S., Hell, S. (2019).
    Molecular contribution function in RESOLFT nanoscopy. Optics Express, 27 (15), 21956-21987.
  • Aspelmeier, T., Charitha, C., Luke, D.R. (2016).
    Local Linear Convergence of the ADMM/Douglas-Rachford Algorithms without Strong Convexity and Application to Statistical Imaging. SIAM Journal on Imaging Sciences, 9, 842-868.
  • Hafi, N., Grunwald, M., van den Heuvel, L. S., Aspelmeier, T., Chen, J.-H., Zagrebelsky, M., Schuette, O. M., Steinem, C., Korte, M., Munk, A., Walla, J. P. (2016).
    Corrigendum: Fluorescence nanoscopy by polarization modulation and polarization angle narrowing. Nature Methods, 13, 101.
  • Hafi, N., Grunwald, M., van den Heuvel, l.S., Aspelmeier, T., Steinem, C., Korte, M., Munk, A., Walla, J.P. (2016).
    Reply to "Polarization modulation adds little additional information to super-resolution fluorescence microscopy" Nature Methods, 13, 8-9.
  • Aspelmeier, T., Egner, A., Munk, A. (2015).
    Modern Statistical Challenges in High Resolution Fluorescence Microscopy. Annual Review of Statistics and its Application, 2, 163-202.
  • Hafi, N., Grunwald, M., van den Heuvel, L.S., Aspelmeier, T., Chen, J.-H., Zagrebelsky, M., Schütte, O.M., Steinem, C., Korte, M., Munk, A., Walla, P.J. (2014).
    Fluorescence nanoscopy by polarization modulation and polarization angle narrowing. Nature Methods, 11, doi: 10.1038/nmeth.2919.
  • Aspelmeier, T., Ebel, G., Engeland, U. (2013).
    Transmission image reconstruction and imaging using Poissonian detector data PCT Patent Application, No. PCT/EP2011/003507.
  • Aspelmeier, T., Ebel, G., Hoeschen, Ch. (2013).
    Tomographic imaging using Poissonian detector data. United States Patent, No. 8,559,690 B2.
  • Aspelmeier, T., Ebel, G., Engeland, U. (2012).
    Radiation dose reductions for images contaminated with Poisson noise. doi: 10.1594/ecr2012/C-1181..
  • Hoeschen, Ch., Rafecas, M., Aspelmeier, T. (2011).
    Algorithms for image reconstruction. In Cantone, M.C., Hoeschen, Ch. (eds.), Radiation physics for nuclear medicine, Springer Verlag, Ch. 12.
  • Aspelmeier, T., Zippelius, A. (2011).
    The integrated density of states of the random graph Laplacian. J. Stat. Phys., 144, 759–773.
  • Vollmayr-Lee, K., Aspelmeier, T., Zippelius, A. (2011).
    Hydrodynamic correlation functions of a driven granular fluid in steady state. Phys. Rev. E, 83, 011301.
  • Aspelmeier, T., Braun, A. (2010).
    Sample-to-sample fluctuations and bond chaos in the m-component spin glass. Phys. Rev. B, 81, 094439.
  • Fiege, A., Aspelmeier, T., Zippelius, A. (2009).
    Long-time tails and cage effect in driven granular fluids. Phys. Rev. Lett., 102, 098001.
  • Ulrich, S., Aspelmeier, T., Roeller, K., Fingerle, A., Herminghaus, S., Zippelius, A. (2009).
    Cooling and aggregation in wet granulates. Phys. Rev. Lett., 102, 148002.
  • Ulrich, S., Aspelmeier, T., Zippelius, A., Roeller, K., Fingerle, A., Herminghaus, S. (2009).
    Dilute wet granular particles: Nonequilibrium dynamics and structure formation. Phys. Rev. E, 80, 031306.
  • Uecker, H., Kranz, W. T., Aspelmeier, T., Zippelius, A. (2009).
    Partitioning of energy in highly polydisperse granular gases. Phys. Rev. E, 80, 041303.
  • Aspelmeier, T., Billoire, A., Marinari, E., Moore, M. A. (2008).
    Finite size corrections in the Sherrington-Kirkpatrick model. J. Phys. A, 41, 324008.
  • Aspelmeier, T. (2008).
    Bond chaos in the Sherrington-Kirkpatrick model. J. Phys. A, 41, 205005.
  • Aspelmeier, T. (2008).
    An exact relation between free energy fluctuations and bond chaos in the Sherrington-Kirkpatrick model. J. Stat. Mech., P04018.
  • Aspelmeier, T. (2008).
    Free-energy fluctuations and chaos in the Sherrington-Kirkpatrick model. Phys. Rev. Lett., 100, 117205.
  • Otto, M., Aspelmeier, T., Zippelius, A. (2006).
    Microscopic dynamics of thin hard rods. J. Chem. Phys., 124, 154907.
  • Braun, A., Aspelmeier, T. (2006).
    The m-component spin glass on a Bethe lattice. Phys. Rev. B, 74, 144205.
  • Aspelmeier, T., Blythe, R. A., Bray, A. J., Moore, M. A. (2006).
    Free energy landscapes, dynamics, and the edge of chaos in mean-field models of spin glasses. Phys. Rev. B, 74, 184411.
  • Jeo, Y., Moore, M. A., Aspelmeier, T. (2005).
    Nature of perturbation theory in spin glasses. J. Phys. A, 38, 4027–4045.
  • Aspelmeier, T., Moore, M. A. (2004).
    Generalized Bose-Einstein phase transition in large-m component spin glasses. Phys. Rev. Lett., 92, 077201.
  • Aspelmeier, T., Bray, A. J., Moore, M. A. (2004).
    Complexity of Ising spin glasses. Phys. Rev. Lett., 92, 087203.
  • Aspelmeier, T., Moore, M. A., Young, A. P. (2003).
    Interface energies in Ising spin glasses. Phys. Rev. Lett., 90, 127202.
  • Aspelmeier, T., Moore, M. A. (2003).
    Free energy fluctuations in Ising spin glasses. Phys. Rev. Lett., 90, 177201.
  • Aspelmeier, T., Magnin, J., Graupner, W., Täuber, U. C. (2002).
    Random walks with imperfect trapping in the decoupled-ring approximation. Eur. Phys. J. B, 28, 441–450.
  • Aspelmeier, T., Bray, A. J., Moore, M. A. (2002).
    Why chaos in spin glasses is hard to observe. Phys. Rev. Lett., 89, 197202.
  • Aspelmeier, T., Schmittmann, B., Zia, R. K. P. (2001).
    Microscopic kinetics and time-dependent structure factors. Phys. Rev. Lett., 87, 065701.
  • Broderix, K., Aspelmeier, T., Hartmann, A. K., Zippelius, A. (2001).
    Stress relaxation of near-critical gels. Phys. Rev. E, 64, 021404.
  • Aspelmeier, T., Huthmann, M., Zippelius, A. (2001).
    Free cooling of particles with rotational degrees of freedom. In Luding, S. and Po ̈schel, Th. (eds.), Granular Gases, number 564 in Lecture Notes in Physics, Berlin/Heidelberg, Springer Verlag..
  • Aspelmeier, T. (2000).
    Microscopic models of energy dissipation by internal degrees of freedom in particle collisions. Phd thesis published online at http://webdoc.sub.gwdg.de/diss/2000/aspelmeier/..
  • Triampo, W., Aspelmeier, T., Schmittmann, B. (2000).
    Universal aspects of vacancy-mediated disordering dynamics: the effect of external fields. Phys. Rev. E, 61, 2386.
  • Aspelmeier, T., Zippelius, A. (2000).
    Dynamics of a one-dimensional granular gas with a stochastic coefficient of restitution. Physica A, 282, 450.
  • Huthmann, M., Aspelmeier, T., Zippelius, A. (1999).
    Granular cooling of hard needles. Phys. Rev. E, 60, 654.
  • Aspelmeier, T., Gerl, F., Zippelius, A. (1998).
    A microscopic model of energy dissipation in granular collisions. In Herrmann, H. J., Hovi, J.-P. , Luding, S. (eds.), Physics of Dry Granular Media, volume 350 of NATO ASI Series, Dordrecht, Kluwer Academic Publishers, 407.
  • Aspelmeier, T., Giese, G., Zippelius, A. (1998).
    Cooling dynamics of a dilute gas of inelastic rods: a many particle simulation. Phys. Rev. E, 57, 857.