Christopher Røhl Yskes Andersen
Project Manager (Physical sciences; Chemical sciences; Quantum physics; Condensed matter physics; Atomic, molecular and optical physics; Classical physics; Structural properties of condensed matter; Surface properties of condensed matter; Electronic and magnetic properties of condensed matter; superconductivity; Condensed matter modelling and density functional theory; Condensed matter imaging; Condensed matter characterisation technique development; Condensed matter physics not elsewhere classified; Lasers and quantum electronics; Atomic and molecular physics; Photonics, optoelectronics and optical communications; Classical and physical optics; Thermodynamics and statistical physics; Electrostatics and electrodynamics; Classical physics not elsewhere classified; Acoustics and acoustical devices; waves)
Copenhagen, Denmark
Professional summary:
My main interest for the recent years is quantum science and technology. I have specialized in the quantum eco-systems and established a broad network of stakeholders within research, companies, GTS-institutions and national authorities.
Research experience:
My research interests and experiences include in situ electron microscopy, neutron and x-ray scattering with a primary emphasis on structural and analytical characterization of nanoparticle catalysts, semiconductor nanowires, and magnetic transition metals. I am experienced in crystal growth, finite element modelling, programming in multiple languages including Python, MATLAB, NI LabVIEW etc., microfabrication, and device and material characterisation.
Publications
- Electrical characterization of nanowires combined with in-situ TEM imaging
- Field-induced magnetic incommensurability in multiferroic Ni3TeO6
- Field-induced magnetic incommensurability in multiferroic Ni3TeO6
- In situTEM modification of individual silicon nanowires and their charge transport mechanisms
- Epitaxial growth of III-V nanowires on Si(111) microheaters using an environmental transmission electron microscope
- Direct Observations of Twin Formation Dynamics in Binary Semiconductors
- Measuring Surface Tension of III-V Nanowire Au-Catalyst Droplets with an E-field
- Direct Observations of Twin Formation Dynamics in Binary Semiconductors
- Magnetic Bloch oscillations and domain wall dynamics in a near-Ising ferromagnetic chain
- Surface tension of Au-catalysed GaAs nanowires
- Electric field effect on Au-assisted III-V nanowire growth
- Local E-field manipulation of III-V nanowire catalysts in an Environmental Transmission Electron Microscope
- The E-field: A tool for IIIV nanowire growth
- Microheater Controlled Crystal Phase Engineering of Nanowires Using In Situ Transmission Electron Microscopy
- Controlling heterostructures with atomic precision in III-V nanowires using microheaters in an in-situ TEM
- Surface tension of Au-catalysed GaAs-nanowires
- Direct observations of nucleation and early-stage growth of Au-catalyzed GaAs nanowires on Si(111)
- Improved droplet elongation model and value for surface tension of AuSi