2024 MRS Fall Meeting & Exhibit
EL07.15.11

Volumetric Photonic Crystal Scintillators

When and Where

Dec 4, 2024
8:00pm - 10:00pm
Hynes, Level 1, Hall A

Presenter(s)

Co-Author(s)

Sachin Vaidya1,Marius Jürgensen2,3,Charles Roques-Carmes1,3,Simo Pajovic1,Shaul Katznelson4,Jonathan Gales2,Joshua Chen1,Steven Kooi1,Ido Kaminer4,Mikael Rechtsman2,Marin Soljačić1

Massachusetts Institute of Technology1,The Pennsylvania State University2,Stanford University3,Technion–Israel Institute of Technology4

Abstract

Sachin Vaidya1,Marius Jürgensen2,3,Charles Roques-Carmes1,3,Simo Pajovic1,Shaul Katznelson4,Jonathan Gales2,Joshua Chen1,Steven Kooi1,Ido Kaminer4,Mikael Rechtsman2,Marin Soljačić1

Massachusetts Institute of Technology1,The Pennsylvania State University2,Stanford University3,Technion–Israel Institute of Technology4
Scintillators are materials that convert high-energy particles, such as X-rays, free electrons, or gamma rays, into optical photons through a complex cascade of processes. These materials are central to various modern imaging technologies, including diagnostic medical imaging and non-destructive testing. Integrating nanophotonics with scintillators represents a promising direction poised to advance several technologies by directly controlling and tailoring the light emission process. For instance, utilizing the Purcell effect can increase the rate of spontaneous emission, yielding significantly brighter scintillators (see: Kurman et al., arXiv:2302.01300 (2023)). This enhancement would directly translate to reduced X-ray dosage in medical settings, thereby decreasing the risk of radiation exposure to patients. Previous approaches have incorporated surface patterns in relatively thin scintillators to enhance the out-coupling of emission (see: Roques-Carmes, Rivera et al., Science 375 (6583), eabm9293 (2022)). Here, we demonstrate the fabrication and characterization of bulk-patterned (volumetric), two-dimensional photonic crystal scintillators that exhibit significant emission enhancement while being several hundred microns thick. Notably, we find that this enhancement results from a combination of bulk and surface effects, arising from the wavelength-scale periodicity of the photonic crystal embedded within the scintillating material

Keywords

optical properties

Symposium Organizers

Viktoriia Babicheva, University of New Mexico
Ho Wai (Howard) Lee, University of California, Irvine
Melissa Li, California Institute of Technology
Yu-Jung Lu, Academia Sinica

Symposium Support

Bronze
APL Quantum
Enlitech
Walter de Gruyter GmbH

Session Chairs

Po-Chun Hsu
Ho Wai (Howard) Lee

In this Session