TY - JOUR
T1 - Scalable Registration of Single Quantum Emitters within Solid Immersion Lenses through Femtosecond Laser Writing
AU - Jones, Alexander
AU - Cheng, Xingrui
AU - Parthasarathy, Shravan Kumar
AU - Arshad, Muhammad Junaid
AU - Cilibrizzi, Pasquale
AU - Nagy, Roland
AU - Salter, Patrick
AU - Smith, Jason
AU - Bonato, Cristian
AU - Bekker, Christiaan
N1 - Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society.
PY - 2025/6/10
Y1 - 2025/6/10
N2 - The precise registration of solid-state quantum emitters to photonic structures is a major technological challenge for fundamental research (e.g. in cavity quantum electrodynamics) and applications to quantum technology. Standard approaches include the complex multistep fabrication of photonic structures on pre-existing emitters, both registered within a grid of lithographically-defined markers. Here, we demonstrate a marker-free, femtosecond laser writing technique to generate individual quantum emitters within photonic structures. Characterization of 28 defect centers, laser-written at the centers of pre-existing solid immersion lens structures, showed offsets relative to the photonic structure's center of 260 nm in the x-direction and 60 nm in the y-direction, with standard deviations of ± 170 and ± 90 nm, respectively, resulting in an average 4.5 times enhancement of the optical collection efficiency. This method is scalable for developing integrated quantum devices using spin-photon interfaces in silicon carbide and is easily extendable to other materials.
AB - The precise registration of solid-state quantum emitters to photonic structures is a major technological challenge for fundamental research (e.g. in cavity quantum electrodynamics) and applications to quantum technology. Standard approaches include the complex multistep fabrication of photonic structures on pre-existing emitters, both registered within a grid of lithographically-defined markers. Here, we demonstrate a marker-free, femtosecond laser writing technique to generate individual quantum emitters within photonic structures. Characterization of 28 defect centers, laser-written at the centers of pre-existing solid immersion lens structures, showed offsets relative to the photonic structure's center of 260 nm in the x-direction and 60 nm in the y-direction, with standard deviations of ± 170 and ± 90 nm, respectively, resulting in an average 4.5 times enhancement of the optical collection efficiency. This method is scalable for developing integrated quantum devices using spin-photon interfaces in silicon carbide and is easily extendable to other materials.
KW - Color Centers
KW - Femtosecond Laser Writing
KW - Qubits
KW - Scalable Quantum Devices
KW - Silicon Carbide
UR - http://www.scopus.com/inward/record.url?scp=105007797019&partnerID=8YFLogxK
U2 - 10.1021/acs.nanolett.5c01325
DO - 10.1021/acs.nanolett.5c01325
M3 - Letter
C2 - 40494848
SN - 1530-6984
JO - Nano Letters
JF - Nano Letters
ER -