Room-temperature single photon emitters in cubic boron nitride nanocrystals

Color centers in wide bandgap semiconductors are attracting broad attention for use as platforms for quantum technologies relying on room-temperature single-photon emission (SPE), and for nanoscale metrology applications building on the centers’ response to electric and magnetic fields. Here, we dem...

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Published inOptical materials express Vol. 10; no. 4; p. 843
Main Authors López-Morales, Gabriel I., Almanakly, Aziza, Satapathy, Sitakanta, Proscia, Nicholas V., Jayakumar, Harishankar, Khabashesku, Valery N., Ajayan, Pulickel M., Meriles, Carlos A., Menon, Vinod M.
Format Journal Article
LanguageEnglish
Published Washington Optical Society of America 01.04.2020
Subjects
Color centers
Cubic boron nitride
Decay rate
Defects
Electronic devices
Emitters
Energy gap
Fluorescence
Line spectra
Nanocrystals
Optoelectronic devices
Photoluminescence
Photon emission
Photons
Room temperature
Wide bandgap semiconductors
Online AccessGet full text
ISSN2159-3930
2159-3930
DOI10.1364/OME.386791

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Abstract Color centers in wide bandgap semiconductors are attracting broad attention for use as platforms for quantum technologies relying on room-temperature single-photon emission (SPE), and for nanoscale metrology applications building on the centers’ response to electric and magnetic fields. Here, we demonstrate room-temperature SPE from defects in cubic boron nitride (cBN) nanocrystals, which we unambiguously assign to the cubic phase using spectrally resolved Raman imaging. These isolated spots show photoluminescence (PL) spectra with zero-phonon lines (ZPLs) within the visible region (496–700 nm) when subject to sub-bandgap laser excitation. Second-order autocorrelation of the emitted photons reveals antibunching with g 2 (0) ∼ 0.2, and a decay constant of 2.75 ns that is further confirmed through fluorescence lifetime measurements. The results presented herein prove the existence of optically addressable isolated quantum emitters originating from defects in cBN, making this material an interesting platform for opto-electronic devices and quantum applications.
AbstractList Color centers in wide bandgap semiconductors are attracting broad attention for use as platforms for quantum technologies relying on room-temperature single-photon emission (SPE), and for nanoscale metrology applications building on the centers’ response to electric and magnetic fields. Here, we demonstrate room-temperature SPE from defects in cubic boron nitride (cBN) nanocrystals, which we unambiguously assign to the cubic phase using spectrally resolved Raman imaging. These isolated spots show photoluminescence (PL) spectra with zero-phonon lines (ZPLs) within the visible region (496–700 nm) when subject to sub-bandgap laser excitation. Second-order autocorrelation of the emitted photons reveals antibunching with g 2 (0) ∼ 0.2, and a decay constant of 2.75 ns that is further confirmed through fluorescence lifetime measurements. The results presented herein prove the existence of optically addressable isolated quantum emitters originating from defects in cBN, making this material an interesting platform for opto-electronic devices and quantum applications.
Color centers in wide bandgap semiconductors are attracting broad attention for use as platforms for quantum technologies relying on room-temperature single-photon emission (SPE), and for nanoscale metrology applications building on the centers' response to electric and magnetic fields. Here, we demonstrate room-temperature SPE from defects in cubic boron nitride (cBN) nanocrystals, which we unambiguously assign to the cubic phase using spectrally resolved Raman imaging. These isolated spots show photoluminescence (PL) spectra with zero-phonon lines (ZPLs) within the visible region (496–700 nm) when subject to sub-bandgap laser excitation. Second-order autocorrelation of the emitted photons reveals antibunching with g2(0) ∼ 0.2, and a decay constant of 2.75 ns that is further confirmed through fluorescence lifetime measurements. The results presented herein prove the existence of optically addressable isolated quantum emitters originating from defects in cBN, making this material an interesting platform for opto-electronic devices and quantum applications.
Author Meriles, Carlos A.
Satapathy, Sitakanta
López-Morales, Gabriel I.
Proscia, Nicholas V.
Ajayan, Pulickel M.
Almanakly, Aziza
Jayakumar, Harishankar
Menon, Vinod M.
Khabashesku, Valery N.
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CitedBy_id crossref_primary_10_1016_j_jcrysgro_2022_126781
crossref_primary_10_1002_adom_202201059
crossref_primary_10_1021_acsomega_2c03785
crossref_primary_10_1016_j_matlet_2025_138011
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SubjectTerms Color centers
Cubic boron nitride
Decay rate
Defects
Electronic devices
Emitters
Energy gap
Fluorescence
Line spectra
Nanocrystals
Optoelectronic devices
Photoluminescence
Photon emission
Photons
Room temperature
Wide bandgap semiconductors
Title Room-temperature single photon emitters in cubic boron nitride nanocrystals
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Volume 10
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