Public Abstract

DE-SC0025700: Discovering a Controlled Mechanism to Pattern Antisite Defect Qubits in CVD-grown Monolayer Transition Metal Dichalcogenides

Award Status: Active

Institution: The Pennsylvania State University, University Park, PA
UEI: NPM2J7MSCF61
DUNS: 003403953

Most Recent Award Date: 01/20/2026
Number of Support Periods: 1
PM: Sefat, Athena

Current Budget Period: 05/01/2025 - 04/30/2026
Current Project Period: 05/01/2025 - 04/30/2028
PI: OZDEN, BURCU

Supplement Budget Period: N/A

Public Abstract

Discovering a controlled mechanism to pattern antisite defect qubits in CVD-grown monolayer Transition Metal Dichalcogenides Dr. Burcu Ozden¹, Assistant Professor Co-PI: Dr. Can Ataca², 1: Penn State Abington, Abington, PA , 19001 2: University of Maryland, Baltimore County, Baltimore, MD , 21250 As the need for secure communication grows in a globally connected world, quantum computing offers a promising pathway to groundbreaking security technologies through quantum bits or qubits. A qubit, unlike a traditional computer bit, can exist in multiple states simultaneously, enabling exceptional computational power for complex tasks such as encrypted communication and advanced simulations. To achieve qubits on an atomic scale, precise material engineering is essential. This project aims to develop and control specific atomic-scale defects in two-dimensional (2D) transition metal dichalcogenides (TMDs), creating an innovative foundation for qubit-based systems. Leveraging proton irradiation, the research will systematically generate and control defects like antisites in materials such as tungsten disulfide (WS2) and tungsten diselenide (WSe2), critical for scalable and stable qubit operation. Through an integrated approach that combines computational modeling and experimental characterization, this project seeks to decode the physics behind defects and establish methods to manipulate these defects without introducing strain or foreign elements, paving the way for qubits that operate at room temperature and are robust enough for practical applications. This research was selected for funding by the Office of [Basic Energy Sciences (BES)]

Discovering a controlled mechanism to pattern antisite defect qubits in CVD-grown monolayer Transition Metal Dichalcogenides

Dr. Burcu Ozden¹, Assistant Professor

Co-PI: Dr. Can Ataca²,

1: Penn State Abington, Abington, PA , 19001

2: University of Maryland, Baltimore County, Baltimore, MD , 21250

As the need for secure communication grows in a globally connected world, quantum computing offers a promising pathway to groundbreaking security technologies through quantum bits or qubits. A qubit, unlike a traditional computer bit, can exist in multiple states simultaneously, enabling exceptional computational power for complex tasks such as encrypted communication and advanced simulations. To achieve qubits on an atomic scale, precise material engineering is essential. This project aims to develop and control specific atomic-scale defects in two-dimensional (2D) transition metal dichalcogenides (TMDs), creating an innovative foundation for qubit-based systems. Leveraging proton irradiation, the research will systematically generate and control defects like antisites in materials such as tungsten disulfide (WS2) and tungsten diselenide (WSe2), critical for scalable and stable qubit operation. Through an integrated approach that combines computational modeling and experimental characterization, this project seeks to decode the physics behind defects and establish methods to manipulate these defects without introducing strain or foreign elements, paving the way for qubits that operate at room temperature and are robust enough for practical applications.

This research was selected for funding by the Office of [Basic Energy Sciences (BES)]