PhD Position Biomechanical Engineering

PhD position in the field of soft tissue biomechanics:
Be part of a translational research project combining experimental and numerical mechanics with AI-based optimization pipelines to improve pediatric orthosis designs.

PhD Position Biomechanical Engineering 100 %

School: School of Engineering

Starting date: immediately or by agreement

• Drive independent research in the field of computational and experimental continuum mechanics
• Collaborate with industrial partners, clinical and research partners within an Innosuisse funded project in the field of biomedical engineering and artificial intelligence
• Publish research results at international conferences and in peer reviewed journals
• Contribute to teaching and supervision of bachelor and master theses

• University Master degree in (bio-)mechanical engineering, material science, civil engineering or similar
• Strong background in continuum mechanics
• Skilled in programming (e.g. Python) and Finite Element simulations
• Experience in performing experiments and analyzing data.
• Motivated to independently navigate an interdisciplinary and collaborative project

We kindly invite you to submit your application by April 5, 2026.

Zurich University of Applied Sciences ZHAW is one of Switzerland's largest multidisciplinary universities of applied sciences, with over 14'000 students and 3'400 faculty and staff.

ZHAW is committed to gender-mixed and diverse teams in order to promote equality, diversity and innovation.

IMES Institute of Mechanical Systems, ZHAW School of Engineering

At the IMES Institute of Mechanical Systems, we drive innovation in Mechanical Engineering through applied research, cutting‑edge technology, and strong industry collaboration. Our interdisciplinary teams develop smart, sustainable solutions in areas such as lightweight structures, mechanical modelling & manufacturing and biomechanics.

The research fields in Biomechanical Engineering (BME) are Surgical Technologies, Soft Tissue Biomechanics and Rehabilitation Engineering. Close collaborations with clinics and industry allow us to translate our engineering approaches into real and patient‑individualised solutions. Within the research field of Soft Tissue Biomechanics
, we develop test set‑ups and protocols to characterise and analyse the non‑linear and viscoelastic response of biological tissues and structures and biomedical materials at different length scales. We combine the experimental approach with numerical models for material model calibration, parameter identification and detailed analyses of the micro‑structural kinematics of multiscale materials. In collaboration with partners in Biology, we perform studies in mechanobiology investigating the interplay between micromechanics and the response of cells.

The BME group consists of a young and interdisciplinary team and is looking for you to drive the applied research of tomorrow.

The PhD is running in the framework of the PhD Programme Biomedical Science and Health Innovations together with ETH Zurich (Co‑Supervision by Prof. Dr. Edoardo Mazza, Experimental Continuum Mechanics Lab). The workspace is located at ZHAW in Winterthur.

https://(Use the "Apply for this Job" box below).-engineering

Experimental Continuum Mechanics Lab,
Department of Mechanical and Process Engineering, ETH Zurich

In an integrated approach, we develop new experimental tools, advanced theories and computational models to investigate the mechanics of biological tissues, soft materials and the mechanobiology of living systems. Characteristic features of soft biological tissues include large strain viscoelasticity, poroelasticity, anisotropy, and loading history dependence of the mechanical response. Their heterogeneous microstructure leads to significant differences of stiffness and kinematics depending on the considered length scale.

The construction, execution, analysis, and interpretation of corresponding experiments represent some of our core activities. Experimental observations are rationalised using advanced continuum models as well as discrete fiber network models. Recent investigations include the study…