Hybrid integration of diamond membranes with GaN waveguides

Research output: Contribution to conferencePoster

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Abstract

The nitrogen vacancy (NV) is a photostable emitter in diamond which is optically accessible at room temperature and a potential candidate for quantum information processing as a spin register. The challenge facing research today is the efficient collection and manipulation of the NV’s emissions, such as by enhancing the zero phonon line transitions for a coherent spin-photon interface.Integrating diamond with other photonic materials would allow for resonant coupling of the defect centre to optical devices on large area photonic integrated circuits (PICs). Emitted photons collected by bus waveguides could then be guided elsewhere on chip for entanglement or measurements.This work focuses on integrating ultra-thin diamond membranes with GaN waveguide and resonator devices. Mode simulations (see Fig. 1(a)) show that light can be coupled significantly into and out of the membranes by this method. Membranes of < 200 nm have been fabricated using Ar-Cl2 etch recipes that cumulatively smooth the diamond over time; an r.m.s roughness value of 0.19 nm has been achieved.1 The smooth surface and ultra-low thickness allow a good conformation and strong bonding of the membrane to other materials. This should allow for the integration of diamond membranes with photonic integrated circuits as shown schematically in Fig. (b).Free standing ultra-thin diamond membranes can also be used in tuneable open access cavities – where a low mode volume and high Q factor are desired; 2 or as templates for fabricating diamond optical devices on non-native substrates.3
Original languageEnglish
Number of pages1
Publication statusPublished - 18 Jun 2017
Event2017 De Beers Diamond Conference - University of Warwick, Warwick, United Kingdom
Duration: 10 Jul 201713 Jul 2017

Conference

Conference2017 De Beers Diamond Conference
CountryUnited Kingdom
CityWarwick
Period10/07/1713/07/17

Fingerprint

diamonds
membranes
waveguides
photonics
integrated circuits
Q factors
registers
photons
manipulators
emitters
roughness
templates
resonators
chips
nitrogen
cavities
defects
room temperature
simulation

Keywords

  • diamonds
  • nitrogen vacancy
  • NV
  • optical devices
  • photonic integrated circuits
  • diamond membranes

Cite this

Hill, P., Liu, H., Gu, E., Dawson, M. D., & Strain, M. J. (2017). Hybrid integration of diamond membranes with GaN waveguides. Poster session presented at 2017 De Beers Diamond Conference, Warwick, United Kingdom.
Hill, P. ; Liu, H. ; Gu, E. ; Dawson, M. D. ; Strain, M. J. / Hybrid integration of diamond membranes with GaN waveguides. Poster session presented at 2017 De Beers Diamond Conference, Warwick, United Kingdom.1 p.
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title = "Hybrid integration of diamond membranes with GaN waveguides",
abstract = "The nitrogen vacancy (NV) is a photostable emitter in diamond which is optically accessible at room temperature and a potential candidate for quantum information processing as a spin register. The challenge facing research today is the efficient collection and manipulation of the NV’s emissions, such as by enhancing the zero phonon line transitions for a coherent spin-photon interface.Integrating diamond with other photonic materials would allow for resonant coupling of the defect centre to optical devices on large area photonic integrated circuits (PICs). Emitted photons collected by bus waveguides could then be guided elsewhere on chip for entanglement or measurements.This work focuses on integrating ultra-thin diamond membranes with GaN waveguide and resonator devices. Mode simulations (see Fig. 1(a)) show that light can be coupled significantly into and out of the membranes by this method. Membranes of < 200 nm have been fabricated using Ar-Cl2 etch recipes that cumulatively smooth the diamond over time; an r.m.s roughness value of 0.19 nm has been achieved.1 The smooth surface and ultra-low thickness allow a good conformation and strong bonding of the membrane to other materials. This should allow for the integration of diamond membranes with photonic integrated circuits as shown schematically in Fig. (b).Free standing ultra-thin diamond membranes can also be used in tuneable open access cavities – where a low mode volume and high Q factor are desired; 2 or as templates for fabricating diamond optical devices on non-native substrates.3",
keywords = "diamonds, nitrogen vacancy, NV, optical devices, photonic integrated circuits, diamond membranes",
author = "P. Hill and H. Liu and E. Gu and Dawson, {M. D.} and Strain, {M. J.}",
year = "2017",
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Hill, P, Liu, H, Gu, E, Dawson, MD & Strain, MJ 2017, 'Hybrid integration of diamond membranes with GaN waveguides' 2017 De Beers Diamond Conference, Warwick, United Kingdom, 10/07/17 - 13/07/17, .

Hybrid integration of diamond membranes with GaN waveguides. / Hill, P.; Liu, H.; Gu, E.; Dawson, M. D.; Strain, M. J.

2017. Poster session presented at 2017 De Beers Diamond Conference, Warwick, United Kingdom.

Research output: Contribution to conferencePoster

TY - CONF

T1 - Hybrid integration of diamond membranes with GaN waveguides

AU - Hill, P.

AU - Liu, H.

AU - Gu, E.

AU - Dawson, M. D.

AU - Strain, M. J.

PY - 2017/6/18

Y1 - 2017/6/18

N2 - The nitrogen vacancy (NV) is a photostable emitter in diamond which is optically accessible at room temperature and a potential candidate for quantum information processing as a spin register. The challenge facing research today is the efficient collection and manipulation of the NV’s emissions, such as by enhancing the zero phonon line transitions for a coherent spin-photon interface.Integrating diamond with other photonic materials would allow for resonant coupling of the defect centre to optical devices on large area photonic integrated circuits (PICs). Emitted photons collected by bus waveguides could then be guided elsewhere on chip for entanglement or measurements.This work focuses on integrating ultra-thin diamond membranes with GaN waveguide and resonator devices. Mode simulations (see Fig. 1(a)) show that light can be coupled significantly into and out of the membranes by this method. Membranes of < 200 nm have been fabricated using Ar-Cl2 etch recipes that cumulatively smooth the diamond over time; an r.m.s roughness value of 0.19 nm has been achieved.1 The smooth surface and ultra-low thickness allow a good conformation and strong bonding of the membrane to other materials. This should allow for the integration of diamond membranes with photonic integrated circuits as shown schematically in Fig. (b).Free standing ultra-thin diamond membranes can also be used in tuneable open access cavities – where a low mode volume and high Q factor are desired; 2 or as templates for fabricating diamond optical devices on non-native substrates.3

AB - The nitrogen vacancy (NV) is a photostable emitter in diamond which is optically accessible at room temperature and a potential candidate for quantum information processing as a spin register. The challenge facing research today is the efficient collection and manipulation of the NV’s emissions, such as by enhancing the zero phonon line transitions for a coherent spin-photon interface.Integrating diamond with other photonic materials would allow for resonant coupling of the defect centre to optical devices on large area photonic integrated circuits (PICs). Emitted photons collected by bus waveguides could then be guided elsewhere on chip for entanglement or measurements.This work focuses on integrating ultra-thin diamond membranes with GaN waveguide and resonator devices. Mode simulations (see Fig. 1(a)) show that light can be coupled significantly into and out of the membranes by this method. Membranes of < 200 nm have been fabricated using Ar-Cl2 etch recipes that cumulatively smooth the diamond over time; an r.m.s roughness value of 0.19 nm has been achieved.1 The smooth surface and ultra-low thickness allow a good conformation and strong bonding of the membrane to other materials. This should allow for the integration of diamond membranes with photonic integrated circuits as shown schematically in Fig. (b).Free standing ultra-thin diamond membranes can also be used in tuneable open access cavities – where a low mode volume and high Q factor are desired; 2 or as templates for fabricating diamond optical devices on non-native substrates.3

KW - diamonds

KW - nitrogen vacancy

KW - NV

KW - optical devices

KW - photonic integrated circuits

KW - diamond membranes

M3 - Poster

ER -

Hill P, Liu H, Gu E, Dawson MD, Strain MJ. Hybrid integration of diamond membranes with GaN waveguides. 2017. Poster session presented at 2017 De Beers Diamond Conference, Warwick, United Kingdom.