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Arno Schindlmayr

Vielteilchentheorie

Center for Optoelectronics and Photonics (CeOPP)

Sonderforschungsbereich Transregio 142

arno.schindlmayr@uni-paderborn.de

458

66 Publications

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[66]

2024 | Journal Article | LibreCat-ID: 52723 |

Meyer, M. T., & Schindlmayr, A. (2024). Derivation of Miller’s rule for the nonlinear optical susceptibility of a quantum anharmonic oscillator. Journal of Physics B: Atomic, Molecular and Optical Physics, 57(9), Article 095001. https://doi.org/10.1088/1361-6455/ad369c

LibreCat | Files available | DOI | WoS

[65]

2022 | Book Chapter | LibreCat-ID: 30288

Schmidt, F., Kozub, A. L., Gerstmann, U., Schmidt, W. G., & Schindlmayr, A. (2022). Electron polarons in lithium niobate: Charge localization, lattice deformation, and optical response. In G. Corradi & L. Kovács (Eds.), New Trends in Lithium Niobate: From Bulk to Nanocrystals (pp. 231–248). MDPI. https://doi.org/10.3390/books978-3-0365-3339-1

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[64]

2022 | Journal Article | LibreCat-ID: 26627 |

Neufeld, S., Schindlmayr, A., & Schmidt, W. G. (2022). Quasiparticle energies and optical response of RbTiOPO4 and KTiOAsO4. Journal of Physics: Materials, 5(1), Article 015002. https://doi.org/10.1088/2515-7639/ac3384

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[63]

2022 | Book Chapter | LibreCat-ID: 29808

Schindlmayr, A. (2022). Programmierung und Computersimulationen. In J. Gerick, A. Sommer, & G. Zimmermann (Eds.), Kompetent Prüfungen gestalten: 60 Prüfungsformate für die Hochschullehre (2nd ed., pp. 270–274). Waxmann. https://doi.org/10.36198/9783838558592

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[62]

2022 | Journal Article | LibreCat-ID: 44088 |

Schmidt, F., Kozub, A. L., Gerstmann, U., Schmidt, W. G., & Schindlmayr, A. (2022). A density-functional theory study of hole and defect-bound exciton polarons in lithium niobate. Crystals, 12(11), Article 1586. https://doi.org/10.3390/cryst12111586

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[61]

2021 | Journal Article | LibreCat-ID: 21946 |

Schmidt, F., Kozub, A. L., Gerstmann, U., Schmidt, W. G., & Schindlmayr, A. (2021). Electron polarons in lithium niobate: Charge localization, lattice deformation, and optical response. Crystals, 11, 542. https://doi.org/10.3390/cryst11050542

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[60]

2021 | Journal Article | LibreCat-ID: 22960 |

Bidaraguppe Ramesh, N., Schmidt, F., & Schindlmayr, A. (2021). Lattice parameters and electronic band gap of orthorhombic potassium sodium niobate K0.5Na0.5NbO3 from density-functional theory. The European Physical Journal B, 94(8), Article 169. https://doi.org/10.1140/epjb/s10051-021-00179-8

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[59]

2021 | Journal Article | LibreCat-ID: 22761 |

Friedrich, C., Blügel, S., & Schindlmayr, A. (2021). Erratum: Efficient implementation of the GW approximation within the all-electron FLAPW method [Phys. Rev. B 81, 125102 (2010)]. Physical Review B, 104(3), Article 039901. https://doi.org/10.1103/PhysRevB.104.039901

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[58]

2021 | Journal Article | LibreCat-ID: 23418 |

Kozub, A. L., Schindlmayr, A., Gerstmann, U., & Schmidt, W. G. (2021). Polaronic enhancement of second-harmonic generation in lithium niobate. Physical Review B, 104, 174110. https://doi.org/10.1103/PhysRevB.104.174110

LibreCat | Files available | DOI | WoS | arXiv

[57]

2020 | Journal Article | LibreCat-ID: 19190 |

Schmidt, F., Kozub, A. L., Biktagirov, T., Eigner, C., Silberhorn, C., Schindlmayr, A., Schmidt, W. G., & Gerstmann, U. (2020). Free and defect-bound (bi)polarons in LiNbO3: Atomic structure and spectroscopic signatures from ab initio calculations. Physical Review Research, 2(4), Article 043002. https://doi.org/10.1103/PhysRevResearch.2.043002

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[56]

2019 | Journal Article | LibreCat-ID: 10014 |

Schmidt, F., Riefer, A., Schmidt, W. G., Schindlmayr, A., Imlau, M., Dobener, F., Mengel, N., Chatterjee, S., & Sanna, S. (2019). Quasiparticle and excitonic effects in the optical response of KNbO3. Physical Review Materials, 3(5), Article 054401. https://doi.org/10.1103/PhysRevMaterials.3.054401

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[55]

2019 | Journal Article | LibreCat-ID: 13365 |

Neufeld, S., Bocchini, A., Gerstmann, U., Schindlmayr, A., & Schmidt, W. G. (2019). Potassium titanyl phosphate (KTP) quasiparticle energies and optical response. Journal of Physics: Materials, 2, 045003. https://doi.org/10.1088/2515-7639/ab29ba

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[54]

2018 | Journal Article | LibreCat-ID: 18466 |

Schindlmayr, A. (2018). Exact formulation of the transverse dynamic spin susceptibility as an initial-value problem. Advances in Mathematical Physics, 2018. https://doi.org/10.1155/2018/3732892

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[53]

2018 | Journal Article | LibreCat-ID: 13410 |

Friedrich, M., Schmidt, W. G., Schindlmayr, A., & Sanna, S. (2018). Erratum: Optical properties of titanium-doped lithium niobate from time-dependent density-functional theory [Phys. Rev. Materials 1, 034401 (2017)]. Physical Review Materials, 2(1). https://doi.org/10.1103/PhysRevMaterials.2.019902

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[52]

2017 | Journal Article | LibreCat-ID: 7481

Riefer, A., Weber, N., Mund, J., Yakovlev, D. R., Bayer, M., Schindlmayr, A., … Schmidt, W. G. (2017). Zn–VI quasiparticle gaps and optical spectra from many-body calculations. Journal of Physics: Condensed Matter, 29(21). https://doi.org/10.1088/1361-648x/aa6b2a

[51]

2017 | Journal Article | LibreCat-ID: 13416 |

Friedrich, M., Schmidt, W. G., Schindlmayr, A., & Sanna, S. (2017). Polaron optical absorption in congruent lithium niobate from time-dependent density-functional theory. Physical Review Materials, 1(5). https://doi.org/10.1103/PhysRevMaterials.1.054406

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[50]

2017 | Journal Article | LibreCat-ID: 10021 |

Friedrich, M., Schmidt, W. G., Schindlmayr, A., & Sanna, S. (2017). Optical properties of titanium-doped lithium niobate from time-dependent density-functional theory. Physical Review Materials, 1(3). https://doi.org/10.1103/PhysRevMaterials.1.034401

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[49]

2017 | Journal Article | LibreCat-ID: 10023 |

Schmidt, F., Landmann, M., Rauls, E., Argiolas, N., Sanna, S., Schmidt, W. G., & Schindlmayr, A. (2017). Consistent atomic geometries and electronic structure of five phases of potassium niobate from density-functional theory. Advances in Materials Science and Engineering, 2017. https://doi.org/10.1155/2017/3981317

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[48]

2016 | Journal Article | LibreCat-ID: 10024 |

Riefer, A., Friedrich, M., Sanna, S., Gerstmann, U., Schindlmayr, A., & Schmidt, W. G. (2016). LiNbO3 electronic structure: Many-body interactions, spin-orbit coupling, and thermal effects. Physical Review B, 93(7). https://doi.org/10.1103/PhysRevB.93.075205

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[47]

2016 | Journal Article | LibreCat-ID: 10025

Friedrich, M., Schindlmayr, A., Schmidt, W. G., & Sanna, S. (2016). LiTaO3 phonon dispersion and ferroelectric transition calculated from first principles. Physica Status Solidi B, 253(4), 683–689. https://doi.org/10.1002/pssb.201552576

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[46]

2015 | Journal Article | LibreCat-ID: 10030

Friedrich, M., Riefer, A., Sanna, S., Schmidt, W. G., & Schindlmayr, A. (2015). Phonon dispersion and zero-point renormalization of LiNbO3 from density-functional perturbation theory. Journal of Physics: Condensed Matter, 27(38). https://doi.org/10.1088/0953-8984/27/38/385402

[45]

2015 | Journal Article | LibreCat-ID: 18470 |

Bouhassoune, M., & Schindlmayr, A. (2015). Ab initio study of strain effects on the quasiparticle bands and effective masses in silicon. Advances in Condensed Matter Physics, 2015, Article 453125. https://doi.org/10.1155/2015/453125

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[44]

2014 | Book Chapter | LibreCat-ID: 18471

Friedrich, C., Şaşıoğlu, E., Müller, M., Schindlmayr, A., & Blügel, S. (2014). Spin excitations in solids from many-body perturbation theory. In C. Di Valentin, S. Botti, & M. Cococcioni (Eds.), First Principles Approaches to Spectroscopic Properties of Complex Materials (Vol. 347, pp. 259–301). Berlin, Heidelberg: Springer. https://doi.org/10.1007/128_2013_518

[43]

2014 | Book Chapter | LibreCat-ID: 18472

Schindlmayr, A. (2014). The GW approximation for the electronic self-energy. In V. Bach & L. Delle Site (Eds.), Many-Electron Approaches in Physics, Chemistry and Mathematics (Vol. 29, pp. 343–357). Cham: Springer. https://doi.org/10.1007/978-3-319-06379-9_19

LibreCat | Files available | DOI

[42]

2014 | Journal Article | LibreCat-ID: 18473

Yanagisawa, S., Morikawa, Y., & Schindlmayr, A. (2014). Theoretical investigation of the band structure of picene single crystals within the GW approximation. Japanese Journal of Applied Physics, 53(5S1). https://doi.org/10.7567/jjap.53.05fy02

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[41]

2014 | Book Chapter | LibreCat-ID: 18474 |

Friedrich, C., & Schindlmayr, A. (2014). Many-body perturbation theory: The GW approximation. In S. Blügel, N. Helbig, V. Meden, & D. Wortmann (Eds.), Computing Solids: Models, ab initio Methods and Supercomputing (Vol. 74, p. A4.1-A4.21). Jülich: Forschungszentrum Jülich.

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[40]

2013 | Book Chapter | LibreCat-ID: 18475

Riefer, A., Rohrmüller, M., Landmann, M., Sanna, S., Rauls, E., Vollmers, N. J., … Schmidt, W. G. (2013). Lithium niobate dielectric function and second-order polarizability tensor from massively parallel ab initio calculations. In W. E. Nagel, D. H. Kröner, & M. M. Resch (Eds.), High Performance Computing in Science and Engineering ‘13 (pp. 93–104). Cham: Springer. https://doi.org/10.1007/978-3-319-02165-2_8

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[39]

2013 | Journal Article | LibreCat-ID: 18476 |

Yanagisawa, S., Morikawa, Y., & Schindlmayr, A. (2013). HOMO band dispersion of crystalline rubrene: Effects of self-energy corrections within the GW approximation. Physical Review B, 88(11). https://doi.org/10.1103/PhysRevB.88.115438

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[38]

2013 | Journal Article | LibreCat-ID: 13525 |

Riefer, A., Sanna, S., Schindlmayr, A., & Schmidt, W. G. (2013). Optical response of stoichiometric and congruent lithium niobate from first-principles calculations. Physical Review B, 87(19). https://doi.org/10.1103/PhysRevB.87.195208

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[37]

2013 | Journal Article | LibreCat-ID: 18479 |

Schindlmayr, A. (2013). Analytic evaluation of the electronic self-energy in the GW approximation for two electrons on a sphere. Physical Review B, 87(7), Article 075104. https://doi.org/10.1103/PhysRevB.87.075104

LibreCat | Files available | DOI | WoS | arXiv

[36]

2012 | Journal Article | LibreCat-ID: 18542

Friedrich, C., Betzinger, M., Schlipf, M., Blügel, S., & Schindlmayr, A. (2012). Hybrid functionals and GW approximation in the FLAPW method. Journal of Physics: Condensed Matter, 24(29). https://doi.org/10.1088/0953-8984/24/29/293201

[35]

2011 | Journal Article | LibreCat-ID: 4091

Wand, M., Schindlmayr, A., Meier, T., & Förstner, J. (2011). Simulation of the ultrafast nonlinear optical response of metal slabs. Physica Status Solidi B, 248(4), 887–891. https://doi.org/10.1002/pssb.201001219

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[34]

2011 | Conference Paper | LibreCat-ID: 4048

Wand, M., Schindlmayr, A., Meier, T., & Förstner, J. (2011). Theoretical approach to the ultrafast nonlinear optical response of metal slabs. CLEO:2011 - Laser Applications to Photonic Applications , Article JTuI59. Conference on Lasers and Electro-Optics 2011, Baltimore, Maryland, United States. https://doi.org/10.1364/CLEO_AT.2011.JTuI59

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[33]

2010 | Book Chapter | LibreCat-ID: 18549

Schindlmayr, A., Friedrich, C., Şaşıoğlu, E., & Blügel, S. (2010). First-principles calculation of electronic excitations in solids with SPEX. In F. M. Dolg (Ed.), Modern and Universal First-Principles Methods for Many-Electron Systems in Chemistry and Physics (Vol. 3, pp. 67–78). München: Oldenbourg. https://doi.org/10.1524/9783486711639.67

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[32]

2010 | Journal Article | LibreCat-ID: 18562

Bouhassoune, M., & Schindlmayr, A. (2010). Electronic structure and effective masses in strained silicon. Physica Status Solidi C, 7(2), 460–463. https://doi.org/10.1002/pssc.200982470

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[31]

2010 | Journal Article | LibreCat-ID: 13573

Thierfelder, C., Sanna, S., Schindlmayr, A., & Schmidt, W. G. (2010). Do we know the band gap of lithium niobate? Physica Status Solidi C, 7(2), 362–365. https://doi.org/10.1002/pssc.200982473

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[30]

2010 | Journal Article | LibreCat-ID: 18560 |

Şaşıoğlu, E., Schindlmayr, A., Friedrich, C., Freimuth, F., & Blügel, S. (2010). Wannier-function approach to spin excitations in solids. Physical Review B, 81(5), Article 054434. https://doi.org/10.1103/PhysRevB.81.054434

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[29]

2010 | Journal Article | LibreCat-ID: 18557

Schindlmayr, A., Friedrich, C., Şaşıoğlu, E., & Blügel, S. (2010). First-principles calculation of electronic excitations in solids with SPEX. Zeitschrift Für Physikalische Chemie, 224(3–4), 357–368. https://doi.org/10.1524/zpch.2010.6110

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[28]

2010 | Journal Article | LibreCat-ID: 18558 |

Friedrich, C., Blügel, S., & Schindlmayr, A. (2010). Efficient implementation of the GW approximation within the all-electron FLAPW method. Physical Review B, 81(12), Article 125102. https://doi.org/10.1103/PhysRevB.81.125102

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[27]

2009 | Journal Article | LibreCat-ID: 18632 |

Feste, S. F., Schäpers, T., Buca, D., Zhao, Q. T., Knoch, J., Bouhassoune, M., … Mantl, S. (2009). Measurement of effective electron mass in biaxial tensile strained silicon on insulator. Applied Physics Letters, 95(18). https://doi.org/10.1063/1.3254330

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[26]

2009 | Conference Paper | LibreCat-ID: 18634 |

Schindlmayr, A. (2009). Optical conductivity of metals from first principles. In D. N. Chigrin (Ed.), Theoretical and Computational Nanophotonics: Proceedings of the 2nd International Workshop (Vol. 1176, Issue 1, pp. 157–159). American Institute of Physics. https://doi.org/10.1063/1.3253897

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[25]

2009 | Journal Article | LibreCat-ID: 18636

Friedrich, C., Schindlmayr, A., & Blügel, S. (2009). Efficient calculation of the Coulomb matrix and its expansion around k=0 within the FLAPW method. Computer Physics Communications, 180(3), 347–359. https://doi.org/10.1016/j.cpc.2008.10.009

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[24]

2008 | Journal Article | LibreCat-ID: 18564 |

Freysoldt, C., Eggert, P., Rinke, P., Schindlmayr, A., & Scheffler, M. (2008). Screening in two dimensions: GW calculations for surfaces and thin films using the repeated-slab approach. Physical Review B, 77(23), Article 235428. https://doi.org/10.1103/PhysRevB.77.235428

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[23]

2007 | Book Chapter | LibreCat-ID: 18588

Schindlmayr, A. (2007). Interaction of radiation with matter. Part II: Light and electrons. In K. Urban, C. M. Schneider, T. Brückel, & S. Blügel (Eds.), Probing the Nanoworld (Vol. 34, p. A1.21-A1.36). Jülich: Forschungszentrum Jülich.

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[22]

2007 | Journal Article | LibreCat-ID: 18589

Botti, S., Schindlmayr, A., Del Sole, R., & Reining, L. (2007). Time-dependent density-functional theory for extended systems. Reports on Progress in Physics, 70(3), 357–407. https://doi.org/10.1088/0034-4885/70/3/r02

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[21]

2007 | Journal Article | LibreCat-ID: 18591 |

Friák, M., Schindlmayr, A., & Scheffler, M. (2007). Ab initio study of the half-metal to metal transition in strained magnetite. New Journal of Physics, 9(1). https://doi.org/10.1088/1367-2630/9/1/005

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[20]

2007 | Book Chapter | LibreCat-ID: 18593

Schindlmayr, A., & Scheffler, M. (2007). Quasiparticle calculations for point defects at semiconductor surfaces. In D. A. Drabold & S. K. Estreicher (Eds.), Theory of Defects in Semiconductors (Vol. 104, pp. 165–192). Berlin, Heidelberg: Springer. https://doi.org/10.1007/11690320_8

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[19]

2007 | Journal Article | LibreCat-ID: 18595

Freysoldt, C., Eggert, P., Rinke, P., Schindlmayr, A., Godby, R. W., & Scheffler, M. (2007). Dielectric anisotropy in the GW space–time method. Computer Physics Communications, 176(1), 1–13. https://doi.org/10.1016/j.cpc.2006.07.018

LibreCat | Files available | DOI | WoS | arXiv

[18]

2006 | Book Chapter | LibreCat-ID: 18601 |

Friedrich, C., & Schindlmayr, A. (2006). Many-body perturbation theory: The GW approximation. In S. Blügel, G. Gompper, E. Koch, H. Müller-Krumbhaar, R. Spatschek, & R. G. Winkler (Eds.), Computational Condensed Matter Physics (Vol. 32, p. A5.1-A5.21). Jülich: Forschungszentrum Jülich.

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[17]

2006 | Book Chapter | LibreCat-ID: 18603 |

Schindlmayr, A. (2006). Time-dependent density-functional theory. In S. Blügel, G. Gompper, E. Koch, H. Müller-Krumbhaar, R. Spatschek, & R. G. Winkler (Eds.), Computational Condensed Matter Physics (Vol. 32, p. A4.1-A4.19). Jülich: Forschungszentrum Jülich.

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[16]

2006 | Book Chapter | LibreCat-ID: 18606 |

Friedrich, C., & Schindlmayr, A. (2006). Many-body perturbation theory: The GW approximation. In J. Grotendorst, S. Blügel, & D. Marx (Eds.), Computational Nanoscience: Do It Yourself! (Vol. 31, pp. 335–355). Jülich: John von Neumann Institute for Computing.

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[15]

2006 | Journal Article | LibreCat-ID: 18597 |

Hedström, M., Schindlmayr, A., Schwarz, G., & Scheffler, M. (2006). Quasiparticle corrections to the electronic properties of anion vacancies at GaAs(110) and InP(110). Physical Review Letters, 97(22), Article 226401. https://doi.org/10.1103/PhysRevLett.97.226401

[14]

2006 | Journal Article | LibreCat-ID: 18599 |

Friedrich, C., Schindlmayr, A., Blügel, S., & Kotani, T. (2006). Elimination of the linearization error in GW calculations based on the linearized augmented-plane-wave method. Physical Review B, 74(4), Article 045104. https://doi.org/10.1103/physrevb.74.045104

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[13]

2005 | Book Chapter | LibreCat-ID: 18608 |

Schindlmayr, A. (2005). Magnetic excitations. In S. Blügel, T. Brückel, & C. M. Schneider (Eds.), Magnetism goes Nano (Vol. 26, p. D1.1-D1.20). Jülich: Forschungszentrum Jülich.

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[12]

2002 | Journal Article | LibreCat-ID: 18610

Hedström, M., Schindlmayr, A., & Scheffler, M. (2002). Quasiparticle calculations for point defects on semiconductor surfaces. Physica Status Solidi B, 234(1), 346–353. https://doi.org/10.1002/1521-3951(200211)234:1%3C346::AID-PSSB346%3E3.0.CO;2-J

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[11]

2001 | Journal Article | LibreCat-ID: 18612 |

Schindlmayr, A., García-González, P., & Godby, R. W. (2001). Diagrammatic self-energy approximations and the total particle number. Physical Review B, 64(23), Article 235106. https://doi.org/10.1103/PhysRevB.64.235106

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[10]

2001 | Journal Article | LibreCat-ID: 18615 |

Tatarczyk, K., Schindlmayr, A., & Scheffler, M. (2001). Exchange-correlation kernels for excited states in solids. Physical Review B, 63(23), Article 235106. https://doi.org/10.1103/PhysRevB.63.235106

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[9]

2001 | Book Chapter | LibreCat-ID: 18614

Schindlmayr, A. (2001). Self-consistency and vertex corrections beyond the GW approximation. In S. G. Pandalai (Ed.), Recent Research Developments in Physics (Vol. 2, pp. 277–288). Transworld Research Network.

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[8]

2000 | Journal Article | LibreCat-ID: 18617 |

Schindlmayr, A. (2000). Decay properties of the one-particle Green function in real space and imaginary time. Physical Review B, 62(19), 12573–12576. https://doi.org/10.1103/PhysRevB.62.12573

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[7]

1999 | Journal Article | LibreCat-ID: 18619

Schindlmayr, A. (1999). Universality of the Hohenberg–Kohn functional. American Journal of Physics, 67(10), 933–934. https://doi.org/10.1119/1.19156

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[6]

1998 | Journal Article | LibreCat-ID: 18620 |

Schindlmayr, A., Pollehn, T. J., & Godby, R. W. (1998). Spectra and total energies from self-consistent many-body perturbation theory. Physical Review B, 58(19), 12684–12690. https://doi.org/10.1103/PhysRevB.58.12684

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[5]

1998 | Journal Article | LibreCat-ID: 18622 |

Schindlmayr, A., & Godby, R. W. (1998). Systematic vertex corrections through iterative solution of Hedin’s equations beyond the GW approximation. Physical Review Letters, 80(8), 1702–1705. https://doi.org/10.1103/PhysRevLett.80.1702

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[4]

1998 | Journal Article | LibreCat-ID: 18624

Pollehn, T. J., Schindlmayr, A., & Godby, R. W. (1998). Assessment of the GW approximation using Hubbard chains. Journal of Physics: Condensed Matter, 10(6), 1273–1283. https://doi.org/10.1088/0953-8984/10/6/011

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[3]

1997 | Journal Article | LibreCat-ID: 18626

Schindlmayr, A. (1997). Excitons with anisotropic effective mass. European Journal of Physics, 18(5), 374–376. https://doi.org/10.1088/0143-0807/18/5/011

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[2]

1997 | Journal Article | LibreCat-ID: 18628 |

Schindlmayr, A. (1997). Violation of particle number conservation in the GW approximation. Physical Review B, 56(7), 3528–3531. https://doi.org/10.1103/PhysRevB.56.3528

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[1]

1995 | Journal Article | LibreCat-ID: 18630 |

Schindlmayr, A., & Godby, R. W. (1995). Density-functional theory and the v-representability problem for model strongly correlated electron systems. Physical Review B, 51(16), 10427–10435. https://doi.org/10.1103/PhysRevB.51.10427

66 Publications

Mark all

[66]

2024 | Journal Article | LibreCat-ID: 52723 |

LibreCat | Files available | DOI | WoS

[65]

2022 | Book Chapter | LibreCat-ID: 30288

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[64]

2022 | Journal Article | LibreCat-ID: 26627 |

LibreCat | Files available | DOI | WoS

[63]

2022 | Book Chapter | LibreCat-ID: 29808

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[62]

2022 | Journal Article | LibreCat-ID: 44088 |

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[61]

2021 | Journal Article | LibreCat-ID: 21946 |

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[60]

2021 | Journal Article | LibreCat-ID: 22960 |

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[59]

2021 | Journal Article | LibreCat-ID: 22761 |

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[58]

2021 | Journal Article | LibreCat-ID: 23418 |

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[57]

2020 | Journal Article | LibreCat-ID: 19190 |

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[56]

2019 | Journal Article | LibreCat-ID: 10014 |

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[55]

2019 | Journal Article | LibreCat-ID: 13365 |

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[54]

2018 | Journal Article | LibreCat-ID: 18466 |

Schindlmayr, A. (2018). Exact formulation of the transverse dynamic spin susceptibility as an initial-value problem. Advances in Mathematical Physics, 2018. https://doi.org/10.1155/2018/3732892

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[53]

2018 | Journal Article | LibreCat-ID: 13410 |

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[52]

2017 | Journal Article | LibreCat-ID: 7481

[51]

2017 | Journal Article | LibreCat-ID: 13416 |

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[50]

2017 | Journal Article | LibreCat-ID: 10021 |

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[49]

2017 | Journal Article | LibreCat-ID: 10023 |

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[48]

2016 | Journal Article | LibreCat-ID: 10024 |

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[47]

2016 | Journal Article | LibreCat-ID: 10025

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[46]

2015 | Journal Article | LibreCat-ID: 10030

[45]

2015 | Journal Article | LibreCat-ID: 18470 |

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[44]

2014 | Book Chapter | LibreCat-ID: 18471

[43]

2014 | Book Chapter | LibreCat-ID: 18472

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[42]

2014 | Journal Article | LibreCat-ID: 18473

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[41]

2014 | Book Chapter | LibreCat-ID: 18474 |

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[40]

2013 | Book Chapter | LibreCat-ID: 18475

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[39]

2013 | Journal Article | LibreCat-ID: 18476 |

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[38]

2013 | Journal Article | LibreCat-ID: 13525 |

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[37]

2013 | Journal Article | LibreCat-ID: 18479 |

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[36]

2012 | Journal Article | LibreCat-ID: 18542

[35]

2011 | Journal Article | LibreCat-ID: 4091

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[34]

2011 | Conference Paper | LibreCat-ID: 4048

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[33]

2010 | Book Chapter | LibreCat-ID: 18549

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[32]

2010 | Journal Article | LibreCat-ID: 18562

Bouhassoune, M., & Schindlmayr, A. (2010). Electronic structure and effective masses in strained silicon. Physica Status Solidi C, 7(2), 460–463. https://doi.org/10.1002/pssc.200982470

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[31]

2010 | Journal Article | LibreCat-ID: 13573

Thierfelder, C., Sanna, S., Schindlmayr, A., & Schmidt, W. G. (2010). Do we know the band gap of lithium niobate? Physica Status Solidi C, 7(2), 362–365. https://doi.org/10.1002/pssc.200982473

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[30]

2010 | Journal Article | LibreCat-ID: 18560 |

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[29]

2010 | Journal Article | LibreCat-ID: 18557

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[28]

2010 | Journal Article | LibreCat-ID: 18558 |

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[27]

2009 | Journal Article | LibreCat-ID: 18632 |

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[26]

2009 | Conference Paper | LibreCat-ID: 18634 |

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[25]

2009 | Journal Article | LibreCat-ID: 18636

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[24]

2008 | Journal Article | LibreCat-ID: 18564 |

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[23]

2007 | Book Chapter | LibreCat-ID: 18588

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[22]

2007 | Journal Article | LibreCat-ID: 18589

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[21]

2007 | Journal Article | LibreCat-ID: 18591 |

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[20]

2007 | Book Chapter | LibreCat-ID: 18593

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[19]

2007 | Journal Article | LibreCat-ID: 18595

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[18]

2006 | Book Chapter | LibreCat-ID: 18601 |

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[17]

2006 | Book Chapter | LibreCat-ID: 18603 |

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[16]

2006 | Book Chapter | LibreCat-ID: 18606 |

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[15]

2006 | Journal Article | LibreCat-ID: 18597 |

[14]

2006 | Journal Article | LibreCat-ID: 18599 |

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[13]

2005 | Book Chapter | LibreCat-ID: 18608 |

Schindlmayr, A. (2005). Magnetic excitations. In S. Blügel, T. Brückel, & C. M. Schneider (Eds.), Magnetism goes Nano (Vol. 26, p. D1.1-D1.20). Jülich: Forschungszentrum Jülich.

LibreCat | Files available | Download (ext.)

[12]

2002 | Journal Article | LibreCat-ID: 18610

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[11]

2001 | Journal Article | LibreCat-ID: 18612 |

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[10]

2001 | Journal Article | LibreCat-ID: 18615 |

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[9]

2001 | Book Chapter | LibreCat-ID: 18614

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[8]

2000 | Journal Article | LibreCat-ID: 18617 |

Schindlmayr, A. (2000). Decay properties of the one-particle Green function in real space and imaginary time. Physical Review B, 62(19), 12573–12576. https://doi.org/10.1103/PhysRevB.62.12573

LibreCat | Files available | DOI | WoS | arXiv

[7]

1999 | Journal Article | LibreCat-ID: 18619

Schindlmayr, A. (1999). Universality of the Hohenberg–Kohn functional. American Journal of Physics, 67(10), 933–934. https://doi.org/10.1119/1.19156

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[6]

1998 | Journal Article | LibreCat-ID: 18620 |

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[5]

1998 | Journal Article | LibreCat-ID: 18622 |

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[4]

1998 | Journal Article | LibreCat-ID: 18624

LibreCat | Files available | DOI | WoS | arXiv

[3]

1997 | Journal Article | LibreCat-ID: 18626

Schindlmayr, A. (1997). Excitons with anisotropic effective mass. European Journal of Physics, 18(5), 374–376. https://doi.org/10.1088/0143-0807/18/5/011

LibreCat | Files available | DOI | arXiv

[2]

1997 | Journal Article | LibreCat-ID: 18628 |

Schindlmayr, A. (1997). Violation of particle number conservation in the GW approximation. Physical Review B, 56(7), 3528–3531. https://doi.org/10.1103/PhysRevB.56.3528

LibreCat | Files available | DOI | WoS | arXiv

[1]

1995 | Journal Article | LibreCat-ID: 18630 |

Arno Schindlmayr

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