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Dr.  Marco Berghoff

Dr. Marco Berghoff

Gebäude449
Tel.+49 721 608-29334

E-Mailmarco berghoffMlm7∂kit edu
Scientific Computing and Simulation
Mitarbeiter / Mitarbeiterinnen

Steinbuch Centre for Computing
Hermann-von-Helmholtz-Platz 1
76344 Eggenstein-Leopoldshafen

Forschung

Supercomputer

Das Höchstleistungsrechnen (HPC – vom englischen High Performance Computing) beschäftigt sich mit der Lösung von schwierigen Problemen, die auf einzelnen Computer nicht lösbar sind. Sei es weil die Berechnung zu lange dauert oder der Speicher nicht ausreicht. Der besondere Augenmerk liegt dabei auf eine skalierbare parallele Kommunikation auf eine hohe Performance auf Knotenebene und das Auslassen von nicht benötigten Berechnungen.

Mit NAStJA ist ein Framework entstanden, welches effizient skalenübergreifende Simulationen durchführen kann. Zudem ist es so flexibel designet worden, das schnell experimentelle Lösungsansätze ausprobiert werden können. NAStJA ermöglicht es vollkommen autonom das Rechengebiet dynamisch anzupassen und kommt dabei ohne kollektive Kommunikationen aus.

Anwendungen

Kristalline Phasenfeldmethode

Klassische Phasenfeldmethode

Zelluläre Automaten für biologische Anwendungen

Veröffentlichungen


Buchaufsätze
Application of Large-Scale Phase-Field Simulations in the Context of High-Performance Computing.
Hötzer, J.; Jainta, M.; Ben Said, M.; Steinmetz, P.; Berghoff, M.; Nestler, B.
2016. High Performance Computing in Science and Engineering ’15: Transactions of the High Performance Computing Center, Stuttgart (HLRS) 2015. Ed.: W. Nagel, 659–674, Springer International Publishing, Berlin. doi:10.1007/978-3-319-24633-8_42
Zeitschriftenaufsätze
Massively Parallel Stencil Code Solver with Autonomous Adaptive Block Distribution.
Berghoff, M.; Kondov, I.; Hötzer, J.
2018. IEEE transactions on parallel and distributed systems, 29 (10), 2282–2296. doi:10.1109/TPDS.2018.2819672
Calibration of a multi-phase field model with quantitative angle measurement.
Hötzer, J.; Tschukin, O.; Ben Said, M.; Berghoff, M.; Jainta, M.; Barthelemy, G.; Smorchkov, N.; Schneider, D.; Selzer, M.; Nestler, B.
2016. Journal of materials science, 51 (4), 1788–1797. doi:10.1007/s10853-015-9542-7
Compound Droplets on Fibers.
Weyer, F.; Ben Said, M.; Hötzer, J.; Berghoff, M.; Dreesen, L.; Nestler, B.; Vandewalle, N.
2015. Langmuir, 31 (28), 7799–7805. doi:10.1021/acs.langmuir.5b01391
Phase field crystal modeling of ternary solidification microstructures.
Berghoff, M.; Nestler, B.
2015. Computational condensed matter, 4, 46–58. doi:10.1016/j.cocom.2015.08.002
Prediction of heat conduction in open-cell foams via the diffuse interface representation of the phase-field method.
August, A.; Ettrich, J.; Rölle, M.; Schmid, S.; Berghoff, M.; Selzer, M.; Nestler, B.
2015. International Journal of Heat and Mass Transfer, 84, 800–808. doi:10.1016/j.ijheatmasstransfer.2015.01.052
Scale-bridging phase-field simulations of microstructure responses on nucleation in metals and colloids.
Berghoff, M.; Nestler, B.
2014. European physical journal special topics, 223 (3), 409–419. doi:10.1140/epjst/e2014-02099-8
Adaptive Gitterverfahren für großskalige Mikrostruktursimulationen.
Kröger, P.; Berghoff, M.; Reichardt, M.; Nestler, B.
2013. Forschung aktuell (1613-4958), 2013, 74–77
Phase-field simulations at the atomic scale in comparison to molecular dynamics.
Berghoff, M.; Selzer, M.; Nestler, B.
2013. The ScientificWorld journal, 2013, 564272. doi:10.1155/2013/564272
Efficient techniques for bridging from atomic to mesoscopic scale in phase-field simulations.
Berghoff, M.; Selzer, M.; Choudhury, A.; Nestler, B.
2013. Journal of Computational Methods in Sciences and Engineering, 13 (5-6), 441–454. doi:10.3233/JCM-130476
A phase-field study of large-scale dendrite fragmentation in Al-Cu.
Wesner, E.; Choudhury, A.; August, A.; Berghoff, M.; Nestler, B.
2012. Journal of crystal growth, 359 (1), 107–121. doi:10.1016/j.jcrysgro.2012.08.036
Proceedingsbeiträge
On the Quality of Wall Time Estimates for Resource Allocation Prediction.
Soysal, M.; Berghoff, M.; Klusáček, D.; Streit, A.
2019. ICPP 2019 Proceedings of the 48th International Conference on Parallel Processing: Workshops, Kyoto, Japan — August 05 - 08, 2019, Artikel Nr.: 23 /1–8, ACM Press, New York (NY). doi:10.1145/3339186.3339204
Using On-demand File Systems in HPC Environments.
Soysal, M.; Berghoff, M.; Zirwes, T.; Vef, M.-A.; Oeste, S.; Brinkman, A.; Nagel, W. E.; Streit, A.
2019. The 17th Annual Meeting of the 2019 International Conference on High Performance Computing & Simulation (HPCS 2019), Dublin, IR, July 15-19, 2019
Non-Collective Scalable Global Network Based on Local Communications.
Berghoff, M.; Kondov, I.
2018. 9th Workshop on Latest Advances in Scalable Algorithms for Large-Scale Systems (ScalA), Dallas, TX, USA, November 12, 2018, 25–32, IEEE, Piscataway (NJ). doi:10.1109/ScalA.2018.00007
Analysis of Job Metadata for Enhanced Wall Time Prediction.
Soysal, M.; Berghoff, M.; Streit, A.
2018. Job Scheduling Strategies for Parallel Processing : 22nd International Workshop, JSSPP 2018, Vancouver, BC, Canada, May 25, 2018, Revised Selected Papers. Ed.: Dalibor Klusáček, 14 S., Springer, Cham. doi:10.1007/978-3-030-10632-4_1
Massively parallel phase-field simulations for ternary eutectic directional solidification.
Bauer, M.; Hötzer, J.; Jainta, M.; Steinmetz, P.; Berghoff, M.; Schornbaum, F.; Godenschwager, C.; Köstler, H.; Nestler, B.; Rüde, U.
2015. International Conference for High Performance Computing, Networking, Storage and Analysis, SC 2015; Austin; United States; 15 November 2015 through 20 November 2015, Art.Nr.: 8, ACM, New York (NY). doi:10.1145/2807591.2807662
Vorträge
The NAStJA Framework and the Design of High-performance Application.
Berghoff, M.
2019, August 29. GridKa School (2019), Karlsruhe, Deutschland, 26.–30. August 2019
On the Quality of Wall Time Estimates for Resource Allocation Prediction.
Soysal, M.; Berghoff, M.; Klusáček, D.; Streit, A.
2019, August 5. 15th International Workshop on Scheduling and Resource Management for Parallel and Distributed Systems in conjunction with International Conference on Parallel Processing (ICPP) (SRMPDS 2019), Kyōto, Japan, 5. August 2019
Using On-Demand File Systems in HPC Environments.
Soysal, M.; Berghoff, M.; Zirwes, T.; Vef, M.-A.; Oeste, S.; Brinkmann, A.; Nagel, W. E.; Streit, A.
2019, Juli 17. 17th International Conference on High Performance Computing & Simulation (HPCS 2019), Dublin, Irland, 15.–19. Juli 2019
Multiscale Modeling: Tumor Development.
Rosenbauer, J.; Berghoff, M.; Schug, A.
2019, Juni 20. 3rd ISC Workshops - ISC High Performance (2019), Frankfurt am Main, Deutschland, 16.–20. Juni 2019
Non-Collective Scalable Global Network Based on Local Communications.
Berghoff, M.; Kondov, I.
2018, November 12. 9th Workshop on Latest Advances in Scalable Algorithms for Large-Scale Systems (ScalA 2018), Dallas, TX, USA, 11.–16. November 2018
Analysis of Job Metadata for Enhanced Wall Time Prediction.
Soysal, M.; Berghoff, M.; Streit, A.
2018. JSSPP (2018), Vancouver, Kanada, 21.–25. Mai 2018
Computersimulationen und Supercomputer.
Berghoff, M.
2017, November 15. Junge Talente – Wissenschaft und Musik, Karlsruhe, 27. September 2017
A Global Network for Non-Collective Communication in Autonomous Systems.
Berghoff, M.; Kondov, I.
2017. ICCS 2017, The International Conference on Computational Science, Zürich, Switzerland, 12th - 14th June 2017
Scale-Bridging Phase-Field Simulations of Microstructure Responses on Nucleation in Metals and Colloids.
Berghoff, M.; Nestler, B.
2014. SPP1296 Abschlusskolloquium, Bayreuth, 2014
Scale-Bridging Phase-Field Simulations of Microstructure Responses on Nucleation in Metals and Colloids.
Berghoff, M.; Nestler, B.
2013. SPP1296-Final Meeting, Raunheim, 2013
Scale-Bridging Simulation from Atomistic to Mesoscopic Length Scale.
Berghoff, M.; Selzer, M.; Nestler, B.; Rozas, R. E.; Horbach, J.
2012. Materials Science and Engineering Congress (MSE 2018), Darmstadt, Deutschland, 26.–28. September 2018
Scale-Bridging Phase-Field Simulations of Microstructure Responses on Nucleation in Metals and Colloids.
Berghoff, M.; Nestler, B.
2011. SPP1296-Kick Off Meeting, Stuttgart, 2011
Scale-Bridging Phase-Field Simulations of Microstructure Responses on Nucleation in Metals and Colloids.
Berghoff, M.; Nestler, B.
2011. SPP DFG Begutachtung, Bayreuth, 2011
Scale-Bridging Simulation on Atomistic and Mesoscopic Length Scales.
Berghoff, M.; Nestler, B.
2011. MRS Spring Meeting, San Francisco, 25-29 April 2011
Scale-Bridging Simulation on Atomistic and Mesoscopic Length Scales.
Berghoff, M.; Nestler, B.
2011. 75. Jahrestagung der DPG und DPG Frühjahrstagung, Dresden, 13. - 18. März 2011
Phase-field crystal model for fcc structures.
Berghoff, M.; Nestler, B.
2010. SPP Fokustreffen, Mainz, 2010
Phase-Field Crystal Simulation.
Berghoff, M.; Nestler, B.
2010. SPP1296-Kick Off Meeting, Aachen, January 2010
Poster
Large Scale Simulations of Cell Resolved Tissue by a Cellular Potts Model.
Rosenbauer, J.; Berghoff, M.; Schug, A.
2019, März. 63rd Annual Meeting of the Biophysical Society (BPS 2019), Baltimore, MD, USA, 2.–6. März 2019
The NAStJA Framework: Non-Collective Scalable Global Communications.
Berghoff, M.; Kondov, I.
2018, November. International Conference for High Performance Computing, Networking, Storage, and Analysis (SC 2018), Dallas, TX, USA, 11.–16. November 2018
The NAStJA Framework - Efficient and Flexible.
Berghoff, M.; Kondov, I.
2018, September. International Symposium on Computational Science at Scale (CoSaS 2018), Erlangen, Deutschland, 5.–7. September 2018
Cellular Potts Models for Neural Tissue Simulations.
Rosenbauer, J.; Berghoff, M.; Schug, A.
2018, März 12. DPG-Frühjahrstagung und EPS-CMD27, Berlin, 11-16. März 2018
Large-Scale and Massively Parallel Phase-Field Simulations of Pattern Formation in Ternary Eutectic Alloys.
Hötzer, J.; Bauer, M.; Jainta, M.; Steinmetz, P.; Berghoff, M.; Schornbaum, F.; Godenschwager, C.; Köstler, H.; Rüde, U.; Nestler, B.
2015. SC15, Austin, TX, November 16 - 19 in Austin, Texas, USA
Lamellar eutectic simulations in ternary phase-field crystal.
Berghoff, M.; Nestler, B.
2014. Multiscale modeling of materials with atomic scale resolution using phase-field-crystal methods, MULTIMAT, Lausanne, 21.- 23. May, 2014
Scale-Bridging Phase-Field Simulations of Microstructure Responses on Nucleation in Metals and Colloids.
Berghoff, M.; Nestler, B.
2014. SPP1296 Abschlusskolloquium, Bayreuth, 2014
Scale-Bridging Phase-Field Simulations of Microstructure Responses on Nucleation in Metals and Colloids.
Berghoff, M.; Selzer, M.; Nestler, B.
2011. SPP DFG Begutachtung, Bayreuth, 2011
Gauging the Phase Field Crystal Model on Simple Systems: Hard Spheres.
Berghoff, M.; Nestler, B.; Oettel, M.; Schilling, T.
2011. DPG-Frühjahrstagung, Dresden, 13.-18. März 2011
Phase-field study of the fragmentation secondary arm in Al-Cu alloys.
Wesner, E.; Choudhury, A.; August, A.; Berghoff, M.; Nestler, B.
2011. Euromat 2011 : European Congress and Exhibition on Advanced Materials and Processes, Montpellier, F, September 12-15, 2011
Populärwissenschaftliche Vorträge
Titel Tagung Autoren Quelle

Junge Talente – Wissenschaft und Musik

Dr. Marco Berghoff

YouTube



Lehre
Titel Typ Semester
Seminar (S) SS 2019
Seminar (S) SS 2018
Vorlesung (V) WS 17/18
Seminar (S) SS 2017