Dieses Bild zeigt Matthias Ruf

Matthias Ruf

Herr M. Sc.

Promovend
Institut für Mechanik (MIB)
Lehrstuhl für Kontinuumsmechanik
[Foto: Matthias Ruf]

Kontakt

+49 711 685 66619
+4971168566347

Pfaffenwaldring 7
70569 Stuttgart
Deutschland
Raum: 3.104

Sprechstunde

nach Vereinbarung

Alle Publikationen:
  1. Balcewicz, M., Siegert, M., Gurris, M., Ruf, M., Krach, D., Steeb, H., & Saenger, E. H. (2021). Digital Rock Physics: A Geological Driven Workflow for the Segmentation of Anisotropic Ruhr Sandstone. Frontiers in Earth Science, 9. https://doi.org/10.3389/feart.2021.673753
  2. Ruf, M., & Steeb, H. (2021). Effects of Thermal Treatment on Acoustic Waves in Carrara Marble Preprint. https://doi.org/10.1002/essoar.10507938.2
  3. Lissa, S., Ruf, M., Steeb, H., & Quintal, B. (2021). Digital rock physics applied to squirt flow. GEOPHYSICS, 86(4), MR235--MR245. https://doi.org/10.1190/geo2020-0731.1
  4. Ruf, M., & Steeb, H. (2021). Effects of Thermal Treatment on Acoustic Waves in Carrara Marble: Measurement Data. DaRUS. https://doi.org/10.18419/DARUS-1862
  5. Ruf, M., Lee, D., Piotrowski, J., Huisman, J. A., & Steeb, H. (2021). micro-XRCT data sets of subflorescent salt crusts from evaporation of MgSO4 solution with 0.64 mol/L initial concentration. DaRUS. https://doi.org/10.18419/DARUS-1848
  6. Ruf, M., Lee, D., Piotrowski, J., Huisman, J. A., & Steeb, H. (2021). micro-XRCT data sets of subflorescent salt crusts from evaporation of MgSO4 solution with 0.32 mol/L initial concentration. DaRUS. https://doi.org/10.18419/DARUS-2002
  7. Ruf, M., Lee, D., Piotrowski, J., Huisman, J. A., & Steeb, H. (2021). micro-XRCT data sets of subflorescent salt crusts from evaporation of MgSO4 solution with 0.96 mol/L initial concentration. DaRUS. https://doi.org/10.18419/DARUS-2003
  8. Ruf, M., Taghizadeh, K., & Steeb, H. (2021). micro-XRCT data sets and in situ measured ultrasonic wave propagation of a pre-stressed monodisperse rubber and glass particle mixture with 50 % volume rubber content. DaRUS. https://doi.org/10.18419/DARUS-2208
  9. Lissa, S., Ruf, M., Steeb, H., & Quintal, B. (2021). Digital rock physics applied to squirt flow. Geophysics, 1--40. https://doi.org/10.1190/geo2020-0731.1
  10. Lee, D., Karadimitriou, N., Ruf, M., & Steeb, H. (2021). Detecting micro fractures with X-ray computed tomography. https://arxiv.org/abs/2103.12821
  11. Ruf, M., Balcewicz, M., Saenger, E. H., & Steeb, H. (2021). Digital rock physics: A geological driven workflow for the segmentation of anisotropic Ruhr sandstone: micro-XRCT data set. DaRUS. https://doi.org/10.18419/DARUS-1152
  12. Ruf, M., Teutsch, T., Alber, S., Steeb, H., & Ressel, W. (2021). micro-XRCT data sets of a stone mastic asphalt drill core before and after a uniaxial compression test (sample 2). DaRUS. https://doi.org/10.18419/DARUS-1641
  13. Schuck, B., Teutsch, T., Alber, S., Ressel, W., Steeb, H., & Ruf, M. (2021). Study of air void topology of asphalt with focus on air void constrictions – a review and research approach. Road Materials and Pavement Design, 1--19. https://doi.org/10.1080/14680629.2021.1907215
  14. Vahid Dastjerdi, S., Steeb, H., Ruf, M., Lee, D., Weinhardt, F., Karadimitriou, N., & Class, H. (2021). micro-XRCT dataset of Enzymatically Induced Calcite Precipitation (EICP) in a microfluidic cell. DaRUS. https://doi.org/10.18419/DARUS-866
  15. Ruf, M., Steeb, H., Gebert, J., Schneider, R., & Helwig, P. (2021). Sample 1 of human femoral heads: micro-XRCT data sets. DaRUS. https://doi.org/10.18419/DARUS-1177
  16. Ruf, M. (2020). Data Envelopment Analysis zur Effizienzbewertung technischer Systeme am Beispiel von Photovoltaik-Anlagen [Bachelorarbeit]. FernUniversität in Hagen.
  17. Lissa, S., Ruf, M., Steeb, H., & Quintal, B. (2020). Effects of crack roughness on attenuation caused by squirt flow in Carrara marble. SEG Technical Program Expanded Abstracts 2020. https://doi.org/10.1190/segam2020-3427789.1
  18. Ruf, M., & Steeb, H. (2020). An open, modular, and flexible micro X-ray computed tomography system for research. Review of Scientific Instruments, 91(11), 113102. https://doi.org/10.1063/5.0019541
  19. Ruf, M., & Steeb, H. (2020). micro-XRCT data set of Carrara marble with artificially created crack network: slow cooling down from 600°C. DaRUS. https://doi.org/10.18419/DARUS-754
  20. Ruf, M., & Steeb, H. (2020). micro-XRCT data set of an in-situ flow experiment with an X-ray transparent flow cell. DaRUS. https://doi.org/10.18419/DARUS-691
  21. Ruf, M., & Steeb, H. (2020). micro-XRCT data set of Carrara marble with artificially created crack network: fast cooling down from 600°C. DaRUS. https://doi.org/10.18419/DARUS-682
  22. Hermann, S., Schneider, M., Flemisch, B., Frey, S., Iglezakis, D., Ruf, M., Schembera, B., Seeland, A., & Steeb, H. (2020). Datenmanagement im SFB 1313. https://doi.org/10.17192/BFDM.2020.1.8085
  23. Schepp, L. L., Ahrens, B., Balcewicz, M., Duda, M., Nehler, M., Osorno, M., Uribe, D., Steeb, H., Nigon, B., Stöckhert, F., Swanson, D. A., Siegert, M., Gurris, M., Saenger, E. H., & Ruf, M. (2020). Digital rock physics and laboratory considerations on a high-porosity volcanic rock: micro-XRCT data sets. DaRUS. https://doi.org/10.18419/DARUS-680
  24. Ruf, M., & Steeb, H. (2020). micro-XRCT data set of open-pored asphalt concrete. DaRUS. https://doi.org/10.18419/DARUS-639
  25. Page, M. A. M., Ruf, M., & Hartmann, S. (2018). Numerical modeling of the thickness dependence of zinc die-cast materials. Computational Mechanics, 62(4), 655--667. https://doi.org/10.1007/s00466-017-1519-8
  26. Ruf, M. (2017). Modellierung der Dickenabhängigkeit einer Zinkdruckguss-Legierung [Masterarbeit]. Technische Universität Clausthal.
  27. Martinez Page, M. A., Ruf, M., & Hartmann, S. (2017). Modeling and Simulation of the Thickness Dependence in Die Casting Structures. PAMM, 17(1), 449–450. https://doi.org/10.1002/pamm.201710194
  28. Ruf, M. (2014). Charakterisierung von faserverstärkten Halbzeugen aus recycelten Kohlenstofffasern für die Verwendung im Flugzeuginnenraum [Bachelorarbeit]. Hochschule für Angewandte Wissenschaften Hamburg.

Begleitende Lehrveranstaltungen (Organisation und Durchführung des Übungsbetriebs):

Sommersemester 2019 Technische Mechanik III: Energiemethoden der Elastostatik, Inkompressible Fluide und Dynamik von Starrkörpern
Wintersemester 2018/19 Technische Mechanik III: Energiemethoden der Elastostatik, Inkompressible Fluide und Dynamik von Starrkörpern
Sommersemester 2018 Technische Mechanik II: Einführung in die Elastostatik und Festigkeitslehre
 
Zum Seitenanfang