11 structural positions at AMOLF in Netherlands

PhD-student: Physical learning machines

to create novel synthetic materials? The aim of another project is to study the interplay of structure, interactions and function in physical learning systems. We aspire to understand how structure and

Internship: Self-organized criticality of light

which a system can dynamically tune itself to a critical point, and from which scale-free structures (aka fractals) emerge organically in the dynamics of the system. While SOC has been theoretically

Phd – student: Nonlinear metaphotonics for UV semiconductor metrology

the NWO research programme NanoXUV we will develop nanophotonic structures that convert infrared wavelengths to coherent structured light of very short wavelength, in the UV and even extreme ultraviolet

Cathodoluminescence tomography for semiconductor device inspection and analysis

structures like nanosheet transistors that are relevant for semiconductor manufacturing and uses tomographic techniques in combination with inverse design and machine learning tools. The aim is to determine

Two PhD positions: Fano4nano – Fano resonance enhanced scatterometry for wafer metrology

structures for application in high-precision semiconductor metrology, guided by design principles from the field of optical metasurfaces. The tremendous success of the semiconductor industry is enabled by

Postdoc : Shining light on atomic scale processes

routinely visualize materials all the way down to the atomic level, revealing unexpected insights into the influence of chemical structure on material properties. At the same time, recent developments in

Internship: Machines that design themselves; inventing green nanomechanical systems using large language models

pacemaker or a wearable fitness monitor) is extremely hard – due to the very large design space (there are infinitely many systems one could build!) and due to the complex relation between device structure

Two PHD positions: Metasurfaces for energy-efficient wave-based computing

Koenderink) aim at developing nanoscale photonic structures, such as plasmonics and metasurfaces, to control scattering, emission, amplification and detection of light. Our work has applications in the domains

Postdoc: Pattern-driven self-organization of multi-cellular systems

to steer the multicellular self-organization, and to generate tissues whose structures and patterning can be designed at will. In this project at the interface of physics and biology, you will use

Postdoc: Single-cell Dynamics in Organoids using 3D imaging and AI Analysis

. These next generation tools will reveal the complex lineage relations between cells, as well as the internal structure of organoid cells. By applying these methods to organoids grown in our labs and that