Fakultät für Mathematik und Naturwissenschaften

Mathematik in der Chemie: Die Suche nach Synthesewegen für neue Medikamente

  1. A. Schuppert, T. Mrziglod, Hybrid model identification and discrimination with practical examples from the chemical industry, Chapter 4 in: Hybrid Modeling in Process Industries (pp. 63-88). CRC Press, 2018.
  2. K. Coböken, G. Mogk, T. Mrziglod, U. Telle, Systems for decisions support in industrial use, In: Computer Aided Chemical Engineering 21 (2006), 2063-2068.
  3. T.J. Struble, J.C. Alvarez, S.P. Brown, et al., Current and future roles of artificial intelligence in medicinal chemistry synthesis, Journal of medicinal chemistry 63(16) (2020), 8667-8682.
  4. J. Uhlemann, H. Diedam, W. Hoheisel, T. Schikarski, W. Peukert, Modeling and Simulation of Process Technology for Nanoparticulate Drug Formulations - A Particle Technology Perspective, Pharmaceutics 13(1) (2021), 22.

Quasikristalle

  1. O. Greis, Quasikristalle, Nachrichten aus Chemie, Technik und Laboratorium 38(11) (1990), 1346-1352.
  2. M. Senechal, What is a quasicrystal, Notices of the AMS, 53(8) (2006), 886-887.
  3. M. Senechal, J.E. Taylor, Quasicrystals: the view from Stockholm, The Mathematical Intelligencer 35(2) (2013), 1-9.
  4. A.J. Bourdillon, Quasicrystals': 2D Tiles in 3D Superclusters, AuthorHouse, 2010.
  5. G. Gottstein, Der atomistische Aufbau der Festkörper, Physikalische Grundlagen der Materialkunde, 2007, Seiten 11-63.
  6. G. Gottstein, Physical foundations of materials science, Springer Science & Business Media, 2013.

 

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