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2019 | OriginalPaper | Buchkapitel

Nitrogen-Vacancy Color Centers in Diamond Fabricated by Ultrafast Laser Nanomachining

verfasst von : Changkun Shi, Huihui Luo, Zongwei Xu, Fengzhou Fang

Erschienen in: Simulation and Experiments of Material-Oriented Ultra-Precision Machining

Verlag: Springer Singapore

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Abstract

Nitrogen-vacancy (NV) color center is one kind of luminescent point defect in diamond. NV color center is a composite structure composed of substituted nitrogen atoms and adjacent carbon vacancies in diamond. It can be applied in many fields, such as super-resolution fluorescence imaging, high-sensitive detection, and quantum computing. In order to meet the requirements of NV color center’s applications, many efforts have been devoted to study the manufacturing methods of NV color center. Nowadays, femtosecond (fs) laser technology has been widely used in the field of micro/nanomachining and gradually applied to the manufacturing of diamond NV color centers. In this chapter, the mechanism and characteristics of fs laser micro/nanomachining, the basic properties, and the applications of diamond NV color centers were concisely summarized. Moreover, the ultrafast laser processing of NV color center, the fluorescence detection of NV color center, and the anti-bunching analysis method of single NV color center are introduced and discussed in detail.

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Vorheriges Kapitel The Contribution of Ion Plasma Sprayed Coating to Performance of Precision Diamond Dressing Tools

Acosta V, Hemmer P (2013) Nitrogen-vacancy centers: physics and applications. MRS Bull 38:127–130CrossRef

Köhler J et al (1993) Magnetic resonance of a single molecular spin. Nature 363(6426):242–244CrossRef

Wrachtrup J et al (1993) Optical detection of magnetic resonance in a single molecule. Nature 363(6426):244–245CrossRef

Gruber A (1997) Scanning confocal optical microscopy and magnetic resonance on single defect centers. Science 276(5321):2012–2014CrossRef

Balasubramanian G et al (2009) Ultralong spin coherence time in isotopically engineered diamond. Nat Mater 8(5):383–387CrossRef

Acosta VM et al (2010) Optical properties of the nitrogen-vacancy singlet levels in diamond. Phys Rev B 82(20):2889–2898CrossRef

Rondin L et al (2015) Magnetometry with nitrogen-vacancy defects in diamond. Cheminform 45(42):056503

Mcguinness LP et al (2011) Quantum measurement and orientation tracking of fluorescent nanodiamonds inside living cells. Nat Nanotechnol 6(6):358–363CrossRef

Schuster DI et al (2010) High-cooperativity coupling of electron-spin ensembles to superconducting cavities. Phys Rev Lett 105(14):140501CrossRef

10.

Maletinsky P et al (2012) A robust scanning diamond sensor for nanoscale imaging with single nitrogen-vacancy centres. Nat Nanotechnol 7(5):320CrossRef

11.

Kubanek A et al (2012) Quantum interference of single photons from two remote nitrogen-vacancy centers in diamond. In: Meeting of the APS division of atomic, molecular and optical physics

12.

Schell AW et al (2014) Scanning single quantum emitter fluorescence lifetime imaging: quantitative analysis of the local density of photonic states. Nano Lett 14(5):2623–2627CrossRef

13.

Cuche A et al (2010) “Deterministic” quantum plasmonics. Nano Lett 10(11):4566CrossRef

14.

Zaitsev SAM (2001) Optical Properties of Diamond. Springer, Berlin, Heidelberg, pp 5090–5097CrossRef

15.

Koizumi S, Nebel CE, Nesladek M (2008) Physics and applications of CVD diamond. Wiley, Weinheim

16.

Jelezko F, Wrachtrup J (2010) Single defect centres in diamond: a review. Phys Status Solidi 203(13):3207–3225CrossRef

17.

Mildren, Assoc. Rich P, Rabeau AJR (2013) Optical quality diamond grown by chemical vapor deposition. Optical engineering of diamond. Wiley‐VCH Verlag GmbH & Co. KGaA

18.

Suter D, Jelezko F (2017) Single-spin magnetic resonance in the nitrogen-vacancy center of diamond. Prog Nucl Magn Reson Spectrosc 98–99:50CrossRef

19.

Davies G, Hamer MF (1976) Optical studies of the 1.945 eV vibronic band in diamond. Proc R Soc Math Phys Eng Sci 348(1653):285–298CrossRef

20.

Doherty MW et al (2013) The nitrogen-vacancy colour centre in diamond. Phys Rep 528(1):1–45CrossRef

21.

Wang J (2016) Preparation and spin coherence of NV centers in diamond and temperature detection application. University of Science Technology of China

22.

Liu Y (2016) Generation of single photons based on color centers in diamond and investigation on its fluorescence dynamics. East China Normal University

23.

Balasubramanian G et al (2014) Nitrogen-vacancy color center in diamond-emerging nanoscale applications in bioimaging and biosensing. Curr Opin Chem Biol 20(20):69–77CrossRef

24.

Orwa JO et al (2011) Engineering of nitrogen-vacancy color centers in high purity diamond by ion implantation and annealing. J Appl Phys 109(8):3207CrossRef

25.

Plakhotnik T, Aman H (2017) NV-centers in nanodiamonds: how good they are. Diam Relat Mater 82:87–95CrossRef

26.

Berthel M et al (2016) Photophysics of single nitrogen-vacancy centers in diamond nanocrystals. Phys Rev B 91(3):035308

27.

Felton S et al (2008) Electron paramagnetic resonance studies of the neutral nitrogen vacancy in diamond. Phys Rev B: Condens Matter 77(77):439–446

28.

Lenef A, Rand SC (1996) Electronic structure of the N-V center in diamond: theory. Phys Rev B: Condens Matter 53(56):13427–13440CrossRef

29.

Manson NB, Harrison JP, Sellars MJ (2006) Nitrogen-vacancy center in diamond: model of the electronic structure and associated dynamics. Phys Rev B Cond matter 74(10):104303

30.

Fuchs GD et al (2011) A quantum memory intrinsic to single nitrogen–vacancy centres in diamond. Nat Phys 7(10):789–793CrossRef

31.

Kong X (2015) Magnetic resonance towards single nuclear spin sensitivity based on single solidstate spin in diamond. University of Science and Technology of China

32.

Dumeige Y et al (2014) Magnetometry with nitrogen-vacancy ensembles in diamond based on infrared absorption in a doubly resonant optical cavity. Phys Rev B 87(15):155202CrossRef

33.

Nizovtsev AP et al (2001) Modeling fluorescence of single nitrogen–vacancy defect centers in diamond. Phys B Phys Condens Matter 308(308):608–611CrossRef

34.

Lesik M (2015) Engineering of NV color centers in diamond for their applications in quantum information and magnetometry

35.

Gisin N et al (2001) Quantum cryptography. Rev Mod Phys 74(1):145–195MATHCrossRef

36.

Groeblacher S et al (2005) Experimental quantum cryptography with qutrits. New J Phys 8(5):75

37.

Dutt MVG et al (2007) Quantum register based on individual electronic and nuclear spin qubits in diamond. Science 316(5829):1312–1316CrossRef

38.

Bernien H et al (2012) Heralded entanglement between solid-state qubits separated by 3 meters. In: APS division of atomic, molecular and optical physics meeting

39.

Tsukanov AV (2013) Quantum memory based on ensemble states of NV centers in diamond. Russ Microlectron 42(3):127–147CrossRef

40.

Rivas A, Huelga SF, Plenio MB (2010) Entanglement and non-markovianity of quantum evolutions. Phys Rev Lett 105(5):050403

41.

Abe E, Sasaki K (2018) Tutorial: magnetic resonance with nitrogen-vacancy centers in diamond—microwave engineering, materials science, and magnetometry. J Appl Phys 123(16):161101CrossRef

42.

Maze JR et al (2008) Nanoscale magnetic sensing with an individual electronic spin in diamond. Nature 455(7213):644–647CrossRef

43.

Dolde F et al (2011) Electric-field sensing using single diamond spins. Nat Phys 7(6):459–463CrossRef

44.

Glenn DR et al (2018) High-resolution magnetic resonance spectroscopy using a solid-state spin sensor. Nature 555(7696):351CrossRef

45.

Grazioso F et al (2013) Measurement of the full stress tensor in a crystal using photoluminescence from point defects: the example of nitrogen vacancy centers in diamond. Appl Phys Lett 103(10):133CrossRef

46.

Kucsko G et al (2013) Nanometer scale quantum thermometry in a living cell. Physics 500(7460):54–58

47.

Ajoy A et al (2015) Atomic-scale nuclear spin imaging using quantum-assisted sensors in diamond. Phys. Rev X 5(1):011001

48.

Fu CC et al (2007) Characterization and application of single fluorescent nanodiamonds as cellular biomarkers. Proc Natl Acad Sci U S A 104(3):727–732CrossRef

49.

Neugart Felix et al (2007) Dynamics of diamond nanoparticles in solution and cells. Nano Lett 7(12):3588–3591CrossRef

50.

Fang CY et al (2011) The exocytosis of fluorescent nanodiamond and its use as a long-term cell tracker. Small 7(23):3363–3370CrossRef

51.

Mohan N et al (2010) In vivo imaging and toxicity assessments of fluorescent nanodiamonds in Caenorhabditis elegans. Nano Lett 10(9):3692–3699CrossRef

52.

Simpson DA et al (2014) In vivo imaging and tracking of individual nanodiamonds in drosophila melanogaster embryos. Biomed Opt Express 5(4):1250–1261CrossRef

53.

Kuo Y et al (2013) Fluorescent nanodiamond as a probe for the intercellular transport of proteins in vivo. Biomaterials 34(33):8352–8360CrossRef

54.

Wu TJ et al (2013) Tracking the engraftment and regenerative capabilities of transplanted lung stem cells using fluorescent nanodiamonds. Nat Nanotechnol 8(9):682–689CrossRef

55.

Han KY et al (2009) Optimizing fluorophores for super-resolution fluorescence STED microscopy. Biophys J 96(3):637a–637aMathSciNetCrossRef

56.

Rittweger E et al (2015) STED microscopy reveals crystal colour centres with nanometric resolution. Nat Photonics 3(3):144–147CrossRef

57.

Wildanger D et al (2012) Solid immersion facilitates fluorescence microscopy with nanometer resolution and sub-ångström emitter localization. Adv Mater 24(44): OP309–OP313CrossRef

58.

Mazur E (2008) Femtosecond laser micromachining in transparent materials. Nat Photonics 2(4):219–225CrossRef

59.

Schaffer CB, Brodeur A, Mazur E, Laser-induced breakdown and damage in bulk transparent materials induced by tightly focused femtosecond laser pulses. Measur Sci Technol 12(11):1784–1794CrossRef

60.

Ams M et al (2008) Investigation of ultrafast laser-photonic material interactions: challenges for directly written glass photonics. IEEE J Sel Top Quant Electron 14(5):1370–1381CrossRef

61.

Mao SS et al (2004) Dynamics of femtosecond laser interactions with dielectrics. Appl Phys A 79(7):1695–1709CrossRef

62.

Tan D et al (2016) Femtosecond laser induced phenomena in transparent solid materials: fundamentals and applications. Prog Mater Sci 76(1):154–228CrossRef

63.

Qiu J, Miura K, Hirao K (2008) Femtosecond laser-induced microfeatures in glasses and their applications. J Non-Cryst Solids 354(12–13):1100–1111CrossRef

64.

Mysyrowicz A et al (2003) Femtosecond laser irradiation stress induced in pure silica. Opt Express 11(9):1070–1079CrossRef

65.

Joglekar AP et al (2004) Optics at critical intensity: applications to nanomorphing. Proc Natl Acad Sci U S A 101(16):5856–5861CrossRef

66.

Macandrew JA (1988) The programme. Optica Acta Int J Opt 303–316

67.

Kane DJ, Trebino R (1993) Using phase retrieval to measure the intensity and phase of ultrashort pulses: frequency-resolved optical gating. J Opt Soc Am A 10(5):1101–1111CrossRef

68.

Trebino R et al (1997) Measuring ultrashort laser pulses in the time-frequency domain using frequency-resolved optical gating. Rev Sci Instrum 68(9):3277–3295CrossRef

69.

Meijer J (2004) Laser beam machining (LBM), state of the art and new opportunities. J Mater Process Technol 149(1):2–17CrossRef

70.

Küper S, Stuke M (1988) Ablation of uv-transparent materials with femtosecond UV excimer laser pulses. MRS Proc 129(1–4):475–480

71.

Dumeige Y et al (2004) Photo-induced creation of nitrogen-related color centers in diamond nanocrystals under femtosecond illumination. J Lumin 109(2):61–67CrossRef

72.

Wu B et al (2013) Fabrication of nitrogen vacancy color centers by femtosecond pulse laser illumination. Opt Express 21(10):12843–12848CrossRef

73.

Chen YC et al (2016) Laser writing of coherent colour centres in diamond. Nat Photonics 11:77CrossRef

74.

Kononenko VV et al (2017) Nitrogen-vacancy defects in diamond produced by femtosecond laser nanoablation technique. Appl Phys Lett 111(8):081101CrossRef

75.

Sotillo B et al (2017) Visible to infrared diamond photonics enabled by focused femtosecond laser pulses. Micromachines 8(2):60CrossRef

76.

Kasparian J, Sauerbrey R, Chin SL (2000) The critical laser intensity of self-guided light filaments in air. Appl Phys B 71(6):877–879CrossRef

77.

Tzortzakis S et al (2002) Femtosecond laser-guided electric discharge in air. In: Conference digest: 2000 international quantum electronics conference

78.

Kasparian J et al (2003) White-light filaments for atmospheric analysis. Science 301(5629):61–64CrossRef

79.

Sprangle P, Peñano JR, Hafizi B (2002) Propagation of intense short laser pulses in the atmosphere. Phys Rev E Stat Nonlinear Soft Matter Phys 66(2): 046418

80.

Couairon A, Mysyrowicz A (2007) Femtosecond filamentation in transparent media. Phys Rep 441(2):47–189CrossRef

81.

York AG et al (2008) Direct acceleration of electrons in a corrugated plasma waveguide. Phys Rev Lett 100(19):195001CrossRef

82.

Shi L et al (2011) Generation of high-density electrons based on plasma grating induced Bragg diffraction in air. Phys Rev Lett 107(9):095004CrossRef

83.

Lagomarsino S et al (2016) Photoionization of monocrystalline CVD diamond irradiated with ultrashort intense laser pulse. Phys Rev B. 93(8):085128

84.

Sun B, Salter PS, Booth MJ (2014) High conductivity micro-wires in diamond following arbitrary paths. Appl Phys Lett 105(23):397CrossRef

85.

Yamamoto T et al (2013) Extending spin coherence times of diamond qubits by high temperature annealing. Phys Rev B 88(7):4049–4056CrossRef

86.

Chu Y et al (2014) Coherent optical transitions in implanted nitrogen vacancy centers. Nano Lett 14(4):1982–1986CrossRef

87.

Cuche A et al (2009) Near-field optical microscopy with a nanodiamond-based single photon tip. Opt Express 17(22):19969–19980CrossRef

88.

Drezet A et al (2015) Near-field microscopy with a scanning nitrogen-vacancy color center in a diamond nanocrystal: a brief review. Micron 70:55–63CrossRef

89.

Patel RN et al (2015) Efficient photon coupling from a diamond nitrogen vacancy center by integration with silica fiber. Light Sci Appl 5(2):e16032CrossRef

90.

Gaebel T et al (2004) Stable single-photon source in the near infrared. New J of Phys 6(1):98CrossRef

91.

Kurtsiefer C et al (2002) Stable solid-state source of single photons. Phys Rev Lett 85(2):290–293CrossRef

92.

Englund D et al (2010) Deterministic coupling of a single nitrogen vacancy center to a photonic crystal cavity. Nano Lett 10(10):3922CrossRef

93.

Faraon A et al (2011) Resonant enhancement of the zero-phonon emission from a colour centre in a diamond cavity. Nat Photonics 5(5):301–305CrossRef

94.

Riedrichmöller J et al (2011) One- and two-dimensional photonic crystal microcavities in single crystal diamond. Nat Nanotechnol 7(1):69CrossRef

95.

Mclellan CA et al (2015) Patterned formation of highly coherent nitrogen-vacancy centers using a focused electron irradiation technique. Nano Lett 16(4):2450–2454CrossRef

Titel: Nitrogen-Vacancy Color Centers in Diamond Fabricated by Ultrafast Laser Nanomachining
verfasst von: Changkun Shi
Huihui Luo
Zongwei Xu
Fengzhou Fang
Verlag: Springer Singapore
Buch: Simulation and Experiments of Material-Oriented Ultra-Precision Machining
Print ISBN: 978-981-13-3334-7

Electronic ISBN: 978-981-13-3335-4

Copyright-Jahr: 2019
DOI: https://doi.org/10.1007/978-981-13-3335-4_11

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