diff --git a/_bibliography/phdtheses.bib b/_bibliography/phdtheses.bib
index fd288c6..b58eab1 100644
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+++ b/_bibliography/phdtheses.bib
@@ -3,6 +3,28 @@
References
==========
+@phdthesis{Schmidt2026,
+ author = {Schmidt, Christoph Paul},
+ title = {A Computational Framework for Electro-Chemo-Mechanical Analyses of Microstructure-Resolved Solid-State Batteries},
+ year = {2026},
+ school = {Technische Universität München},
+ pages = {150},
+ language = {en},
+ abstract = {This dissertation introduces physics-based non-linear continuum models for solid-state batteries coupling electrochemistry and solid mechanics based on the conservation of charge, mass, and momentum. The efficient formulation and solution of the numerical models allow the investigation of complex electro-chemo-mechanic effects on resolved battery microstructures, including contact and delamination at internal interfaces. The developed models are verified and analyzed to deduce new insights.},
+ url = {https://mediatum.ub.tum.de/1776748},
+}
+
+@phdthesis{Willmann2025,
+ author = {Willmann, Harald},
+ title = {Efficient Inverse Analysis with Coupled Computational Mechanics Models for Fluid-Biofilm Interaction},
+ year = {2025},
+ school = {Technische Universität München},
+ pages = {127},
+ language = {en},
+ abstract = {The modeling of biofilms and their interaction with a surrounding fluid flow is a coupled mechanical problem. The computational methods for fluid-structure interaction and on the experimental side, the observations of the deformation of biofilms have improved recently. In this work, the methodological foundation is laid to use observations on biofilms to build the best fitting mechanical models for biofilms. The search for the best fitting model for a desired result is called inverse analysis.},
+ url = {https://mediatum.ub.tum.de/1734049},
+}
+
@phdthesis{Proell2025,
author = {Pröll, Sebastian David},
school = {Technische Universität München},