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TU/e, PhD Position – Modeling of Magnetically Actuated Microstructures in Soft Materials

Eindhoven University of Technology (TU/e), The Netherlands

The EindhovenUniversity of Technology (TU/e), invites applications for a Ph.D. position Student -Modeling of magnetically actuated microstructures in soft materials – in the Polymer Technology Group, at the Department of Mechanical Engineering, The Netherlands – Jan 2022

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General Info

Position: PhD Position
No. of Positions: 1
Research Field: , ,
Joining Date: ASAP
Contract Period: 4 Years
Salary: According to Standard Norms

Polymer Technology group
Department of Mechanical Engineering
Eindhoven University of Technology (TU/e)
Eindhoven, The Netherlands

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Qualification Details

We are looking for an experienced candidate with an MSc degree (or about to obtain one soon) in mechanical engineering, applied physics, applied mathematics or similar. The candidate should have knowledge of continuum mechanics and numerical methods (such as the finite element method) combined with strong programming and mathematical skills and a good physical intuition. Experience with rheology or constitutive modelling are a plus. The ideal candidatehas excellent scientific skills as well as excellent soft skills related to verbal and written communication (in English).

Responsibilities/Job Description

We are looking for a PhD student for a four-year research project on the topic of numerical modeling of magnetically actuated microstructures as in-situ sensors for characterizing local (bio)mechanical properties of soft (biological) materials. In this project you will develop a computational framework, using the finite element method, to characterize and predict complex material parameters from the time-dependent deformation of magnetic microstructures with external actuation, based on experimental data.

How to Apply?

Online Application through "Apply Now" Button from this page

Reference Number: V35.5410
(If any, use it in the necessary place)

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Documents Required

We invite you to submit a complete application by using the 'apply now'-button on this page.The application should include a:

  • cover letter (1-page max) in which you describe your motivation and qualifications for the position.
  • detailed Curriculum Vitae.
  • grade list for your BSc and MSc grades and a brief summary of your MSc thesis.
  • list of references with full contact information (including the supervisors of your final BSc and final MSc projects).
  • at least one recommendation letter.

We look forward to your application and will screen it as soon as we have received it. Only complete applications will be considered. Review of applications will begin immediately and continue until the position is filled. Promising candidates will be contacted by email. Starting date of the position is as soon as possible.

We do not respond to applications that are sent to us in a different way.

Please keep in mind you can upload only 5 documents up to 2 MB each. If necessary please combine files.


About the Project

Local rheological properties are important in many biomechanical processes, such as extracellular matrix (ECM) remodeling during cancer metastasis, where the material is heterogeneous at the micrometer scale. However, measurements at this scale are not possible with traditional rheometers since these measure an integrated response of an entire millimeter scale sample. In this project, we will develop a numerical framework for using magnetic microstructures as local rheometers for soft materials. The microstructures are, for example, spherical or rod-shaped particles, or artificial cilia that are actuated with an external magnetic field to locally “probe” the (bio)material. The first step is the development of an accurate physical model of the magnetic forces that act on the magnetic microstructure, coupled to the hydrodynamic problem, assuming non-Newtonian material behavior. State of the art FEM modeling will be used to generate high-fidelity data for a given magnetic actuation field and constitutive properties of the material to be probed. Model validation will be done using experiments on well-characterized model materials, e.g., hydrogels. The high-fidelity data will subsequently be used in a reduced order model, which is capable of quickly predicting the response of the magnetic microstructures as a function of the applied magnetic field. The reduced order model will then be used in an inverse problem, where we will obtain local rheological information about the material, given observations of the motion of the magnetic microstructures, and create a real-time, in-situ, 3D mapping of the rheological properties of the material. Finally, we will use the developed methodology to analyze experiments on challenging biomaterials such as mucus and extracellular matrix materials. The PhD position is in the Polymer Technology group, in collaboration with the Microsystems group.

About the Department

Mechanical Engineering

The Department of Mechanical Engineering (W) has been a core part of the TU/e since it was founded in 1956. The department focuses on providing the industry with scientifically educated and application-driven engineers, is a breeding ground for leading international research, and collaborates closely with industry. It offers a Bachelor's program, four Master's programs, and consists of several research groups that focus on long-term, general, system-oriented research. The crux of the department is devoted to designing, analyzing, improving and manufacturing new products and processes, as well as the materials needed for this. The department is fully discipline-oriented and is structured along disciplines – such as mechanics, materials, thermodynamics, fluid mechanics, control, systems and design to name but a few. Application areas such as nano- and micro-scale technology and automotive technology are pursued in different discipline groups as a joint effort.

About the Employer: Eindhoven University of Technology (TU/e)

Conditions of Employment

  • We offer a challenging job for four years in a highly motivated team at a dynamic and ambitious University. You will be part of a highly profiled multidisciplinary collaboration where expertise of a variety of disciplines comes together. The TU/e is located in one of the smartest regions of the world and part of the European technology hotspot ‘Brainport Eindhoven’; well-known because of many high-tech industries and start-ups.A place to be for talented scientists!
  • A full-time employment for four years, with an intermediate evaluation (go/no-go) after nine months.
  • To develop your teaching skills, you will spend 10% of your employment on teaching tasks.
  • To support you during your PhD and to prepare you for the rest of your career, you will make a Training and Supervision plan and you will have free access to a personal development program for PhD students (PROOF program).
  • A gross monthly salary and benefits (such as a pension scheme, pregnancy and maternity leave, partially paid parental leave) in accordance with the Collective Labor Agreement for Dutch Universities.
  • Additionally, an annual holiday allowance of 8% of the yearly salary, plus a year-end allowance of 8.3% of the annual salary.
  • Should you come from abroad and comply with certain conditions, you can make use of the so-called ‘30% facility’, which permits you not to pay tax on 30% of your salary.
  • A broad package of fringe benefits, including an excellent technical infrastructure, moving expenses, and savings schemes.
  • Family-friendly initiatives are in place, such as an international spouse program, and excellent on-campus children day care and sports facilities.

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Contact details

Do you recognize yourself in this profile and would you like to know more about the project?Please contact dr. N.O. Jaensson (n.o.jaensson[at] or dr. Y. Wang (y.wang2[at]

For information about terms of employment, click here or contact HRServices.gemini[at]

Please visit to find out more about working at TU/e!

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