The lecture is switching between computer and lecture room, or the corhort is divided into two rooms for group work.
Lectureroom: Cog1030 / Computerroom: Cog0320

Room: AIB Building, Room 1020/1030

Learning content: Planning, realisation, documentation and presentation of a scientific project.

The project content consists of three main elements:

• physical modelling,
• numerical methods and
• programming techniques.

The aim is to teach students the three above-mentioned aspects of computational physics as part of a holistic solution to
a complex physical problem.

The project task consists of developing a physics-based model (a digital twin) for the thermal simulation of a
3D printing process (e.g., selective laser melting).

Key content:
? Modelling of the thermal 3D printing process
? Analysis of transient temperature development as a function of process parameters, material
properties, and the design of the generated component

2SWS lecture + 2SWS exercises
Room: AIB Building, Room 1020/1030

The lecture provides an overview of the most important numerical methods, algorithms, and software
techniques for the computational solution of complex problems at the interface between physics,
engineering, and materials science.

The lecture is primarily aimed at physics students interested in the practical application of physical
modelling in modern industries such as aerospace, energy, microelectronics and medicine.

Key contents:
? Introduction to the most important numerical methods
? Detailed consideration of the finite element method (FEM);
? Learning how to use the commercial FEM simulation software;
? Derivation of analytical solutions to partial differential equations and comparison of analytical results
with results of numerical simulation;
? Individual project work on the practical application of numerical simulation to solve a complex,
industry-relevant problem.

times by arrangement
22.10.2025 / 10:15 - 11:00 h / Introduction, room U2110
24.10.2025 / 10:15 - 11:00 h / Introduction, room U2110
29.10.2025 / 09:00 - 10:00 h / Safety Instructions, room U2110
19.11.2025 / 10:00 - 17:00 h / First Lab Day
07.01.2026 / 10:00 – 17:00 h / Second Lab Day

This course has 2 semester weekly hours (1,5x lecture + 0,5 example classes). The course will start on 10 December 2025.

times by arrangement
Introductory meeting: 15.10.2025, NW1 S1360

The lecture is switching between computer and lecture room, or the corhort is divided into two rooms for group work.
Lectureroom: Cog1030 / Computerroom: Cog0320

times by arrangement

The lecture is switching between computer and lecture room, or the corhort is divided into two rooms for group work.
Lectureroom: Cog1030 / Computerroom: Cog0320

times by arrangement

In dieser Veranstaltung werden mathematische Modelle aus dem Gebiet der Komplexen Systeme behandelt. W?chentlich werden dafür wissenschaftliche Publikationen vorgestellt und diskutiert. Die Auswahl der Themen richtet sich nach aktueller Forschung und dem Interesse der Teilnehmer. Eine Auswahl an m?glichen Modellen (inkl. Referenz) findet sich hier:

https://www.complexity-explorables.org/explorables/

Die Veranstaltung richtet sich haupts?chlich an Studenten des M.Sc. Physik. Bachelorstudenten und Studenten aus anderen Fachdisziplinen sind ebenfalls willkommen!

Informationen zur Veranstaltung: /de/universitaet/campus/veranstaltungskalender/kategorie/physikalisches-kolloquium/

lecture: HS 2010 (gro?er H?rsaal in der Keksdose)
practical fire drill: Emmy-Noether-Str. behind the SFG Building

Start from 7:45 a.m., please arrive on time.

Afterwards there will be a practical fire extinguishing exercise in the outside area behind the SFG-Building, place outside in the Emmy-Noether-Stra?e. The participants are asked to pay attention to weatherproof clothing and sturdy shoes, because the fire drill takes place outside.

Termin nach Vereinbarung

Veranstaltungsort: Fraunhofer MEVIS, Max-von-Laue-Str. 2

Vortrag: HS 2010 (gro?er H?rsaal in der Keksdose)
praktische Feuerl?schübung: Emmy-Noether-Str. hinter dem SFG Geb?ude

Beginn ab 9:45 Uhr, bitte pünktlich erscheinen.

Im Anschluss (ab ca. 11 Uhr) praktische Feuerl?schübung im Au?enbereich hinter dem SFG-Geb?ude, Platz Emmy-Noether-Stra?e. Die Teilnehmenden werden gebeten, auf wetterfeste Kleidung und festes Schuhwerk zu achten, da die Feuerl?schübung drau?en stattfindet.

We investigate space navigation, including the frame problem and the required prediction of time dilation. For it, we develop measurement instruments that provide a velocity, a location, adequate frames, and a clarifying physical foundation of the typically used celestial reference systems. Moreover, we provide very precise, enlightening and new empirical tests as well as valuable, insightful and new universal anchor points. We show empirically and theoretically, that space consists of regions similar to the celestial reference systems, that move relative to each other.

Moreover, we derive exactly, that these regions are statistical averages of even smaller and rapidly moving volume portions. Therefore, also space is a statistical average of volume portions, and space is structured by these moving regions. We derive the dynamics of the volume portions, and therefrom, we derive the quantum postulates, including generalizations. With these, we derive precise space navigation. In particular, we present the new results in new maps of space and time, for instance in the planetary system. On that basis, we derive spectra in quantum gravity and corresponding experimental tests.

Altogether, we provide exact, insightful, improved and generalized foundations for exact space navigation, exact astronomy of space and time, relativity theory and quantum physics. We provide many tests and predictions, and we propose new experimental tests.

We emphasize that we achieve precise accordance with observation, while we do not execute any fit or use any hypothesis, except evident properties. Thus, we achieve an exceptionally high reliability and evidence. Our result is a derived, clarifying, problem solving and elucidating foundation of present – day physics, including space navigation, astronomy, relativity physics and quantum physics. In particular, we provide a founded and fundamental unification of general relativity and quantum physics. Further results will be derived similarly in a future semester.

We derive our results explicitly. So, every student can derive all results on her or his own. This improves competence, confidence and self – esteem. At the end of this lecture, the students can explain how relativity is improved and used for exact space navigation, and how volume in nature founds present – day physics. Moreover, the topic has a high predictive power, so a Short Research Project can be chosen instead of the Seminar Presentation.

Raum: N4270

www.decisions.uni-bremen.de

Rotunde im Cartesium
Enrique-Schmidt-Str. 5

Alle Lebensformen auf der Erde müssen Entscheidungen in der einen oder anderen Weise treffen, um zu überleben, Nachkommen zu sichern, oder ihre spezifische Nische im ?kosystem unserer Erde auszugestalten und einzunehmen. Im t?glichen Leben f?llen Menschen ununterbrochen Entscheidungen, allein oder zusammen mit anderen. Wir sind uns selbst gewahr. Wir glauben, dass wir bewusste und wissensbasierte Entscheidungen treffen. Im Gegensatz dazu stehen einfache Lebensformen z.B Hydren oder Schleimpilze, die kein Gehirn oder nicht einmal ein Nervensystem haben. Nichtsdestoweniger zeigen sie ein komplexes Verhalten, um optimale Entscheidungen zu treffen, die ihr ?berleben sichern. Fasst man allgemein Entscheidungsprozesse als die Suche nach einer optimalen L?sung auf, lassen sich auch unbelebte Prozesse als Entscheidungsprozesse verstehen, wie sie z.B. in der Logistik, Telekommunikation oder der Robotik auftreten. An den Bremer Universit?ten und Instituten findet sich die Entscheidungsforschung sowohl in den Geistes- und Sozialwissenschaften als auch in den Ingenieur- und Naturwissenschaften. Ein vielf?ltiges F?cherspektrum an der Universit?t Bremen und der Jacobs University tr?gt aktiv zu diesem spannenden Forschungsfeld bei. Im 2-w?chigen Rhythmus werden verschiedene Disziplinen und Sichtweisen dargestellt. Welche Mechanismen von Entscheidungsprozessen gibt es? Existieren, unabh?ngig von einer speziellen Lebensform oder einem speziellen Prozess, gemeinsame universelle Eigenschaften des Entscheidungsverhaltens?