- Understanding the fundamental coupling mechanisms in dielectric continua: piezoelasticity, ferroelasticity, electrostriction and pondomotive forces (k2)
- Analysis of lumped parameter models for the description of fundamental electromechanical coupling mechanisms (k4)
- Application of numerical methods for simulation and analysis of simple problems in the electromechanics of continua (k4)
- Development of smart mechatronical systems using integrated sensors and actuators based on electromechanical coupling mechanisms (k6)
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- Fundamentals of deformable dielectric continua undergoing small deformations and with small electric fields
- Physical effects: ferroelectricity, ferroelasticity, electrostriction, piezoelectricity
- Mathematical models for deformable dielectric continua with small deformations and small electric fields
- Numerical methods for efficient simulation of small deformations and small electric fields of deformable dielectric continua
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