JACoW is a publisher in Geneva, Switzerland that publishes the proceedings of accelerator conferences held around the world by an international collaboration of editors.
@unpublished{shao:sap2023-mopb024,
% --- JACoW template Dec 2024 ---
author = {Z.X. Shao and Z. Dong and L. Wang and T. Zhang and Z.R. Zhou},
title = {{Accelerator-Based High-Throughput Material Physical Property Measurement System in Terahertz Near-Field}},
eventtitle = {14th Symp. Accel. Phys. (SAP'23)},
eventdate = {2023-07-10/2023-07-12},
language = {english},
intype = {presented at},
series = {Symposium on Accelerator Physics},
number = {14},
venue = {Xichang, China},
note = {presented at the 14th Symp. Accel. Phys. (SAP'23) in Xichang, China, unpublished},
abstract = {{Superconductor, multiferroic material, giant magnetoresistance etc.,are keystones to information, energy, optoelectronics industries. Inside the THz band, their common characteristic properties are all related to the THz complex optical constant, and they also strongly interact with the ultrafast THz waves, resulting in many fascinating phenomena in physics. Applying the combinatorial material synthesis technique, a key step in the Materials Genome Initiative (MGI) project, requires a novel ‘step-less¿high-throughput characterization method that is still unavailable today, mainly because of the diffraction limit of the THz waves. In this program we will develop a new high throughput material characterization system under the THz near-field, integrating with varying magnetic, temperature and electrical fields. The system will directly measure the complex dielectric constant tensor, which correlates directly to the superconductor bandgap, magnetoelectric coupling, resistance and dielectric constant in the THz band, and plasmonic resonance. This system will be useful in the MGI project to realize highly efficient material screening, and will thus very helpful for finding new materials.}},
}