Decoherence by Optical Phonons in GaN Defect Single-Photon Emitters

In most single-photon defect emitters, such as those in SiC and diamond, interaction with low-energy acoustic phonons determines the temperature dependence of the decoherence rate and the resulting broadening of the ZPL with the temperature obeys a power law. GaN hosts bright and stable single-photon emitters in the 600 nm to 700 nm wavelength range with strong ZPLs even at room temperature. In this work, we study the temperature dependence of the ZPL spectra of GaN SPEs integrated with solid immersion lenses with the goal of understanding the relevant decoherence mechanisms. At temperatures below ~50 K, the ZPL lineshape is found to be Gaussian and the ZPL linewidth is temperature independent and dominated by spectral diffusion. Above ~50 K, the linewidth increases monotonically with the temperature and the lineshape evolves into a Lorentzian. Quite remarkably, the temperature dependence of the linewidth does not follow a power law. We propose a model in which decoherence caused by absorption/emission of optical phonons in an elastic Raman process determines the temperature dependence of the lineshape and the linewidth. Our model explains the temperature dependence of the ZPL linewidth and lineshape in the entire 10 K to 270 K temperature range explored in this work. The ~19 meV optical phonon energy extracted by fitting the model to the data matches remarkably well the ~18 meV zone center energy of the lowest optical phonon band (E2(low)) in GaN. Our work sheds light on the mechanisms responsible for linewidth broadening in GaN SPEs. Since a low energy optical phonon band (E2(low)) is a feature of most group III-V nitrides with a wurtzite crystal structure, including hBN and AlN, we expect our proposed mechanism to play an important role in defect emitters in these materials as well.

[1]  D. Englund,et al.  Investigation of the Stark Effect on a Centrosymmetric Quantum Emitter in Diamond. , 2021, Physical review letters.

[2]  H. Atwater,et al.  Temperature-dependent Spectral Emission of Hexagonal Boron Nitride Quantum Emitters on Conductive and Dielectric Substrates , 2021, Physical Review Applied.

[3]  M. Toth,et al.  Site control of quantum emitters in gallium nitride by polarity , 2021 .

[4]  Baoquan Sun,et al.  Single Photon Emission from Point Defects in Aluminum Nitride Films. , 2020, The journal of physical chemistry letters.

[5]  M. Toth,et al.  Effects of microstructure and growth conditions on quantum emitters in gallium nitride , 2018, APL Materials.

[6]  D. Englund,et al.  Photophysics of GaN single-photon emitters in the visible spectral range , 2017, 1708.09161.

[7]  Australia.,et al.  Photodynamics of quantum emitters in hexagonal boron nitride revealed by low-temperature spectroscopy , 2017, 1704.06881.

[8]  Dirk Englund,et al.  Bright Room‐Temperature Single‐Photon Emission from Defects in Gallium Nitride , 2016, Advanced materials.

[9]  D. Englund,et al.  Solid-state single-photon emitters , 2016, Nature Photonics.

[10]  Dirk Englund,et al.  Bright and photostable single-photon emitter in silicon carbide , 2016 .

[11]  M. Spencer,et al.  Temperature Dependence of Wavelength Selectable Zero-Phonon Emission from Single Defects in Hexagonal Boron Nitride. , 2016, Nano letters.

[12]  Igor Aharonovich,et al.  Quantum emission from hexagonal boron nitride monolayers , 2015, 2016 Conference on Lasers and Electro-Optics (CLEO).

[13]  Jian-Wei Pan,et al.  Single quantum emitters in monolayer semiconductors. , 2014, Nature nanotechnology.

[14]  I. Gerhardt,et al.  Microscopic diamond solid-immersion-lenses fabricated around single defect centers by focused ion beam milling. , 2014, The Review of scientific instruments.

[15]  Martin Fischer,et al.  Low-temperature investigations of single silicon vacancy colour centres in diamond , 2012, 1210.3201.

[16]  Christoph Becher,et al.  Photophysics of single silicon vacancy centers in diamond: implications for single photon emission. , 2012, Optics express.

[17]  S. Zhang,et al.  Dynamic Jahn-Teller effect in the NV(-) center in diamond. , 2011, Physical review letters.

[18]  M. R. Wagner,et al.  Phonon deformation potentials in wurtzite GaN and ZnO determined by uniaxial pressure dependent Raman measurements , 2011 .

[19]  J. Rarity,et al.  Nanofabricated solid immersion lenses registered to single emitters in diamond , 2010, 1012.1135.

[20]  N. Gregersen,et al.  A highly efficient single-photon source based on a quantum dot in a photonic nanowire , 2010 .

[21]  Raymond G. Beausoleil,et al.  Observation of the dynamic Jahn-Teller effect in the excited states of nitrogen-vacancy centers in diamond , 2009, OPTO.

[22]  I. Sildos,et al.  Zero‐Phonon Lines: The Effect of a Strong Softening of Elastic Springs in the Excited State , 2002 .

[23]  M. Cardona,et al.  Phonon dispersion curves in wurtzite-structure GaN determined by inelastic x-ray scattering. , 2001, Physical review letters.

[24]  Y. Yamamoto,et al.  Triggered single photons from a quantum dot. , 2000, Physical review letters.

[25]  Mayer,et al.  Stable solid-state source of single photons , 2000, Physical review letters.

[26]  Walter A. Harrison,et al.  Electrons and Phonons , 2000 .

[27]  P. Reineker,et al.  Optical dephasing in defect-rich crystals , 1999 .

[28]  R. H. Silsbee Thermal Broadening of the Mössbauer Line and of Narrow-Line Electronic Spectra in Solids , 1962 .

[29]  T. Ohshima,et al.  A silicon carbide room-temperature single-photon source. , 2013, Nature materials.