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Techniques

Pulsed Laser Deposition

Pulsed Laser Deposiiton Chamber

The main research tool in our laboratory is the pulsed laser deposition chamber (coming soon!). With this technique a KrF excimer laser ionizes a solid target of material which is then deposited on a crystal substrate creating a thin film. This allows deposition of a single atomic layer of material with high precision and the controlled stacking of different atomic layers to create artificial superlattices. This process is monitored in-situ during deposition with reflection high energy diffraction.

 

Atomic force microscopy

In order to create high quality thin films, crystal substrates with large, atomically flat terraces are needed. Atomic force microscopy uses a microscopically sharp tip to map the surface morphology of both substrates and the grown films.

 

X-ray Scattering

The lattice structure of the crystal is its most fundamental property and is probed with x-ray scattering or diffraction. This technique uses a focused, monochromatic x-ray beam to measure reflections from the crystal. These reflections reveal the grown crystal structure, mosaicity, and epitaxial relationship with the substrate.

 

Electronic and Magnetic Transport

The complex behavior of the valence electrons within oxides is the source of their amazing properties. Insight into these behaviors can be obtained by measuring how these electrons respond to application of electric and magnetic fields. We use the Van der Pauw method with both LN2 and helium cryostats to measure resistivity, doping type, carrier mobility and density, and magnetotransport. More advanced transport measurements such as Hall effects are measured with Hall bar geometry achieved with photolithography.

 

Resonant X-ray Absorption Spectroscopy

The electronic occupation of the active elements of ABO3 complex oxides is of fundamental importance for understanding their emergent properties. Resonant x-ray absorption spectroscopy is an element-specific probe that allows extraction of the valence state, orbital occupation, and spin and orbital specific magnetic moments.

 

Resonant Elastic X-ray Scattering

As with resonant x-ray absorption spectroscopy, resonant elastic x-ray scattering is an element specific technique. This measurement allows probing of long-range ordering phenomena of the charge, spin, and orbital states by probing the emergent non-lattice-derived Bragg reflections.

Resonant Elastic X-ray Scattering

Resonant Inelastic X-ray Scattering

While resonant elastic x-ray scattering probes long range ordering, resonant inelastic x-ray scattering allows investigation of the low-energy excited states in a system, such as magnons, excitons, phonons, and etc. Due to the reciprocal space information obtained through scattering the dispersion of these excitations can also be mapped allowing the coupling parameters, such as the magnetic exchange J, to be extracted.

Resonant Inelastic X-Ray Scattering

Angle-Resolved Photoemission Spectroscopy

To probe the low energy band structure within these heterostructures, of particular relevance to topological phenomena, angle-resolved photoemission spectroscopy is used. Here the electrons are ejected from the materials with a monochromatic energy source and the resulting emitted electrons are sorted by energy and measured. This technique allows the mapping of both the energy and momentum dispersion of the occupied electronic states near the Fermi level, revealing the band structure.

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