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2014 | OriginalPaper | Buchkapitel

4. Separate SiC Nanoparticles

verfasst von : Ji-Yang Fan, Paul Kim-Ho Chu

Erschienen in: Silicon Carbide Nanostructures

Verlag: Springer International Publishing

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Abstract

Silicon carbide nanoparticles generally refer to particles about 1–100 nm in size and single crystal in most cases. Silicon carbide nanocrystals smaller than 10 nm are also called SiC quantum dots; in this size regime, on account of the strong spatial confinement of the carriers, SiC nanocrystals exhibit obvious quantum size effects, especially the quantum confinement effect. As a result, the energy gap of the silicon carbide nanocrystals widens and luminescence shifts toward smaller wavelengths (blueshift) gradually as they become smaller. In addition, the quantum yield may be improved by several orders of magnitude relative to that of the bulk materials. Since the dimensions of the nanoparticles are very small, the surface strongly affects their properties. Silicon carbide is a compound semiconductor, and its surface has multiple bonding structures involving Si, C, O, H, and other atoms and so a variety of surface defects can form, consequently resulting in complex luminescence properties. In this chapter, the preparation methods, electronic structures, luminescence properties, and application of silicon carbide nanoparticles are discussed.

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Vorheriges Kapitel Porous SiC

Nächstes Kapitel SiC Nanowires

Hollabaugh CM, Hull DE, Newkirk LR, Petrovic JJ (1983) R.F.-plasma system for the production of ultrafine, ultrapure silicon carbide powder. J Mater Sci 18:3190–3194

Rao NP, Tymiak N, Blum J, Neuman A, Lee HJ, Girshick SL, McMurry PH, Heberlein J (1998) Hypersonic plasma particle deposition of nanostructured silicon and silicon carbide. J Aerosol Sci 29:707–720

Klein S, Winterer M, Hahn H (1998) Reduced-pressure chemical vapor synthesis of nanocrystalline silicon carbide powders. Chem Vap Deposition 4:143–149

Lin H, Gerbec JA, Sushchikh M, McFarland EW (2008) Synthesis of amorphous silicon carbide nanoparticles in a low temperature low pressure plasma reactor. Nanotechnology 19:325601

Huisken F, Kohn B, Alexandrescu R, Cojocaru S, Crunteanu A, Ledoux G, Reynaud C (1999) Silicon carbide nanoparticles produced by CO₂ laser pyrolysis of SiH₄/C₂H₂ gas mixtures in a flow reactor. J Nanopart Res 1:293–303

Kityk IV, Makowska-Janusik M, Kassiba A, Plucinski KJ (2000) SiC nanocrystals embedded in oligoetheracrylate photopolymer matrices; new promising nonlinear optical materials. Opt Mater 13:449–453

Kassiba A, Tabellout M, Charpentier S, Herlin N, Emery JR (2000) Conduction and dielectric behaviour of SiC nano-sized materials. Solid State Commun 115:389–393

Bouclé J, Kassiba A, Makowska-Janusik M, Sanetra J, Herlin-Boime N, Bulou A, Kodjikian S (2005) Electro-optic phenomena in guest–host films of PMMA and SiC nanocrystals. Opt Commun 246:415–420

Kassiba A, Bednarski W, Pud A, Errien N, Makowska-Janusik M, Laskowski L, Tabellout M, Kodjikian S, Fatyeyeva K, Ogurtsov N, Noskov Y (2007) Hybrid core-shell nanocomposites based on silicon carbide nanoparticles functionalized by conducting polyaniline: electron paramagnetic resonance investigations. J Phys Chem C 111:11544–11551

10.

Kassiba A, Makowska-Janusik M, Bouclé J, Bardeau JF, Bulou A, Herlin-Boime N (2002) Photoluminescence features on the Raman spectra of quasistoichiometric SiC nanoparticles: experimental and numerical simulations. Phys. Rev. B 66:155317

11.

Makowska-Janusik M, Kassiba A, Bouclé J, Bardeau J-F, Kodjikian S, Désert A (2005) Vibrational density of states in silicon carbide nanoparticles: experiments and numerical simulations. J Phys: Condens Matter 17:5101–5110

12.

Bouclé J, Herlin-Boime N, Kassiba A (2005) Influence of silicon and carbon excesses on the aqueous dispersion of SiC nanocrystals for optical application. J Nanopart Res 7:275–285

13.

Herlin-Boime N, Vicens J, Dufour C, Ténégal F, Reynaud C, Rizk R (2004) Flame temperature effect on the structure of SiC nanoparticles grown by laser pyrolysis. J Nanopart Res 6:63–70

14.

Heinrich JL, Curtis CL, Credo GM, Kavanagh KL, Sailor MJ (1992) Luminescent colloidal silicon suspensions from porous silicon. Science 255:66–68

15.

Wu XL, Fan JY, Qiu T, Yang X, Siu GG, Chu PK (2005) Experimental evidence for the quantum confinement effect in 3C-SiC nanocrystallites. Phys Rev Lett 94:026102

16.

Madelung, O.: Semiconductors: Data Handbook. Springer, 3rd ed., Berlin (2004)

17.

Fan JY, Wu XL, Li HX, Liu HW, Siu GG, Chu PK (2006) Luminescence from colloidal 3C-SiC nanocrystals in different solvents. Appl Phys Lett 88:041909

18.

Lehmann V, Gösele U (1991) Porous silicon formation: a quantum wire effect. Appl Phys Lett 58:856–858

19.

Canham LT (1990) Silicon quantum wire array fabrication by electrochemical and chemical dissolution of wafers. Appl Phys Lett 57:1046–1048

20.

Fan JY, Wu XL, Chu PK (2006) Low-dimensional SiC nanostructures: fabrication, luminescence, and electrical properties. Prog Mater Sci 51:983–1031

21.

Fan JY, Li HX, Cui WN (2009) Microstructure and infrared spectral properties of porous polycrystalline and nanocrystalline cubic silicon carbide. Appl Phys Lett 95:021906

22.

Fan JY, Wu XL, Zhao PQ, Chu PK (2006) Stability of luminescent 3C-SiC nanocrystallites in aqueous solution. Phys. Lett. A 360:336–338

23.

Fan JY, Li HX, Cui WN, Dai DJ, Chu PK (2010) Excitation and recombination photodynamics in colloidal cubic SiC nanocrystals. Appl Phys Lett 97:191911

24.

Zhu J, Liu Z, Wu XL, Xu LL, Zhang WC, Chu PK (2007) Luminescent small-diameter 3C-SiC nanocrystals fabricated via a simple chemical etching method. Nanotechnology 18:365603

25.

Fan JY, Li HX, Zhang N, Lu RF (2011) Identification of the reconstruction and bonding structure of SiC nanocrystal surface by infrared spectroscopy. Appl Surf Sci 258:627–630

26.

Wolkin MV, Jorne J, Fauchet PM, Allan G, Delerue C (1999) Electronic states and luminescence in porous silicon quantum dots: the role of oxygen. Phys Rev Lett 82:197–200

27.

Beke D, Szekrényes Z, Balogh I, Veres M, Fazakas É, Varga LK, Kamarás K, Czigány Z, Gali A (2011) Characterization of luminescent silicon carbide nanocrystals prepared by reactive bonding and subsequent wet chemical etching. Appl Phys Lett 99:213108

28.

Beke D, Szekrényes Z, Balogh I, Czigány Z, Kamarás K, Gali A (2013) Preparation of small silicon carbide quantum dots by wet chemical etching. J Mater Res 28:44–49

29.

Liu LZ, Wang J, Wu XL, Li TH, Chu PK (2010) Longitudinal optical phonon–plasmon coupling in luminescent 3C-SiC nanocrystal films. Opt Lett 35:4024–4026

30.

Wu XL, Xiong SJ, Zhu J, Wang J, Shen JC, Chu PK (2009) Identification of surface structures on 3C-SiC nanocrystals with hydrogen and hydroxyl bonding by photoluminescence. Nano Lett 9:4053–4060

31.

Zakharko Yu, Botsoa J, Alekseev S, Lysenko V, Bluet J-M, Marty O, Skryshevsky VA, Guillot G (2010) Influence of the interfacial chemical environment on the luminescence of 3C-SiC nanoparticles. J Appl Phys 107:013503

32.

Li Y, Chen C, Li J-T, Yang Y, Lin Z-M (2011) Surface charges and optical characteristic of colloidal cubic SiC nanocrystals. Nanoscale Res Lett 6:454

33.

Fan JY, Wu XL, Kong F, Qiu T, Huang GS (2005) Luminescent silicon carbide nanocrystallites in 3C-SiC/polystyrene films. Appl Phys Lett 86:171903

34.

Fan JY, Wu XL, Li HX, Liu HW, Huang GS, Siu GG, Chu PK (2006) Si-based solid blue emitters from 3C-SiC nanocrystals. Appl Phys A 82:485–487

35.

Wang J, Xiong SJ, Wu XL, Li TH, Chu PK (2010) Glycerol-bonded 3C-SiC nanocrystal solid films exhibiting broad and stable violet to blue-green emission. Nano Lett. 10:1466–1471

36.

Dai D, Zhang N, Zhang W, Fan J (2012) Highly bright tunable blue-violet photoluminescence in SiC nanocrystal-sodium dodecyl sulfonate crosslinked network. Nanoscale 4:3044–3046

37.

Dai D, Fan J, Zhang N (2011) Synthesis and luminescence properties of silica-coated cubic silicon carbide nanocrystal composites. Micro Nano Lett 6:878–880

38.

Zhang N, Dai D, Zhang W, Fan J (2012) Photoluminescence and light reabsorption in SiC quantum dots embedded in binary-polyelectrolyte solid matrix. J Appl Phys 112:094315

39.

Dai D, Guo X, Fan J (2013) Synthesis and photoluminescence of semiconductor quantum dots/cetyltrimethylammonium bromide vesicle core/shell nanostructures. Appl Surf Sci 276:359–362

40.

Fan JY, Li HX, Wang QJ, Dai DJ, Chu PK (2011) UV-blue photoluminescence from close-packed SiC nanocrystal film. Appl Phys Lett 98:081913

41.

Botsoa J, Bluet JM, Lysenko V, Marty O, Barbier D, Guillot G (2007) Photoluminescence of 6H-SiC nanostructures fabricated by electrochemical etching. J Appl Phys 102:083526

42.

Botsoa J, Bluet JM, Lysenko V, Sfaxi L, Zakharko Y, Marty O, Guillot G (2009) Luminescence mechanisms in 6H-SiC nanocrystals. Phys Rev B 80:155317

43.

Rossi AM, Murphy TE, Reipa V (2008) Ultraviolet photoluminescence from 6H silicon carbide nanoparticles. Appl Phys Lett 92:253112

44.

Fan J, Li H, Wang J, Xiao M (2012) Fabrication and photoluminescence of SiC quantum dots stemming from 3C, 6H, and 4H polytypes of bulk SiC. Appl Phys Lett 101:131906

45.

Matsumoto T, Takahashi J, Tamaki T, Futagi T, Mimura H, Kanemitsu Y (1994) Blue-green luminescence from porous silicon carbide. Appl Phys Lett 64:226–228

46.

Käckell P, Wenzien B, Bechstedt F (1994) Influence of atomic relaxations on the structural properties of SiC polytypes from ab initio calculations. Phys Rev B 50:17037–17046

47.

Yoffe AD (2001) Semiconductor quantum dots and related systems: electronic, optical, luminescence and related properties of low dimensional systems. Adv Phys 50:1–208

48.

Wolfe JP (1982) Thermodynamics of excitons in semiconductors. Phys Today 35:46–54

49.

Fan J, Chu PK (2010) Group IV nanoparticles: synthesis, properties, and biological applications. Small 6:2080–2098

50.

Pol VG, Pol SV, Gedanken A (2005) Novel synthesis of high surface area silicon carbide by RAPET (reactions under autogenic pressure at elevated temperature) of organosilanes. Chem. Mater. 17:1797–1802

51.

Lu A-H, Schmidt W, Kiefer W, Schüth F (2005) High surface area mesoporous SiC synthesized via nanocasting and carbothermal reduction process. J Mater Sci 40:5091–5093

52.

Henderson EJ, Veinot JGC (2009) From phenylsiloxane polymer composition to size-controlled silicon carbide nanocrystals. J Am Chem Soc 131:809–815

53.

Dasog M, Rachinsky C, Veinot JGC (2011) From Si and C encapsulated SiO₂ to SiC: exploring the influence of sol–gel polymer substitution on thermally induced nanocrystal formation. J Mater Chem 21:12422–12427

54.

Yang S, Cai W, Zeng H, Xu X (2009) Ultra-fine β-SiC quantum dots fabricated by laser ablation in reactive liquid at room temperature and their violet emission. J Mater Chem 19:7119–7123

55.

Yang S, Cai W, Zhang H, Zeng H, Lei Y (2011) A general strategy for fabricating unique carbide nanostructures with excitation wavelength-dependent light emissions. J Phys Chem C 115:7279–7284

56.

Yang S, Kiraly B, Wang WY, Shang S, Cao B, Zeng H, Zhao Y, Li W, Liu Z-K, Cai W, Huang TJ (2012) Fabrication and characterization of beaded SiC quantum rings with anomalous red spectral shift. Adv Mater 24:5598–5603

57.

Zakharko Y, Rioux D, Patskovsky S, Lysenko V, Marty O, Bluet JM, Meunier M (2011) Direct synthesis of luminescent SiC quantum dots in water by laser ablation. Phys Status Solidi-R 5:292–294

58.

Sasaki Y, Nishina Y, Sato M, Qkamura K (1989) Optical-phonon states of SiC small particles studied by Raman scattering and infrared absorption. Phys Rev B 40:1762–1772

59.

Yang Z-G, Shaw LL (1996) Synthesis of nanocrystalline SiC at ambient temperature through high energy reaction milling. Nanostruct Mater 7:873–886

60.

Zhang GQ, Wei GD, Zheng KZ, Li L, Xu DP, Wang DY, Xue YF, Su WH (2010) The synthesis of beta-SiC nanoparticles by high-energy mechanical ball milling and their photoluminescence properties. J Nanosci Nanotechnol 10:1951–1955

61.

Martin H-P, Ecke R, Müller E (1998) Synthesis of nanocrystalline silicon carbide powder by carbothermal reduction. J Eur Ceram Soc 18:l737–l1742

62.

Dasog M, Smith LF, Purkait TK, Veinot JGC (2013) Low temperature synthesis of silicon carbide nanomaterials using a solid-state method. Chem Commun 49:7004–7006

63.

Wang CH, Chang YH, Yen MY, Peng CW, Lee CY, Chiu HT (2005) Synthesis of silicon carbide nanostructures via a simplified Yajima process-reaction at the vapor-liquid interface. Adv Mater 17:419–422

64.

Shen G, Chen D, Tang K, Qian Y, Zhang S (2003) Silicon carbide hollow nanospheres, nanowires and coaxial nanowires. Chem Phys Lett 375:177–184

65.

Wang H, Yu J-S, Li X-D, Kim D-P (2004) Inorganic polymer-derived hollow SiC and filled SiCN sphere assemblies from a 3DOM carbon template. Chem Commun 20:2352–2353

66.

Liu Z, Ci L, Jin-Phillipp NY, Rühle M (2007) Vapor-solid reaction for silicon carbide hollow spherical nanocrystals. J Phys Chem C 111:12517–12521

67.

Li P, Xu L, Qian Y (2008) Selective synthesis of 3C-SiC hollow nanospheres and nanowires. Cryst Growth Des 8:2431–2436

68.

Ju Z, Xu L, Pang Q, Xing Z, Ma X, Qian Y (2009) The synthesis of nanostructured SiC from waste plastics and silicon powder. Nanotechnology 20:355604

69.

Ye J, Zhang S, Lee WE (2012) Novel low temperature synthesis and characterisation of hollow silicon carbide spheres. Micropor Mesopor Mat 152:25–30

70.

Baklouti S, Pagnoux C, Chartier T, Baumard JF (1997) Processing of aqueous α-Al₂O₃, α-SiO₂ and α-SiC suspensions with polyelectrolytes. J Eur Ceram Soc 17:1387–1392

71.

Tartaj P, Reece M, Moya JS (1998) Electrokinetic behavior and stability of silicon carbide nanoparticulate dispersions. J Am Ceram Soc 81:389–394

72.

Médout-Marère V, Ghzaoui AEl, Charnay C, Douillard JM, Chauveteau G, Partyka S (2000) Surface heterogeneity of passively oxidized silicon carbide particles: hydrophobic-hydrophilic partition. J Colloid Interf Sci 223:205–214

73.

Zhu X, Tang F, Suzuki TS, Sakka Y (2003) Role of the initial degree of ionization of polyethylenimine in the dispersion of silicon carbide nanoparticles. J Am Ceram Soc 86:189–191

74.

Singh BP, Jena J, Besra L, Bhattacharjee S (2007) Dispersion of nano-silicon carbide (SiC) powder in aqueous suspensions. J Nanopart Res 9:797–806

75.

Che J, Wang X, Xiao Y, Wu X, Zhou L, Yuan W (2007) Effect of inorganic-organic composite coating on the dispersion of silicon carbide nanoparticles in non-aqueous medium. Nanotechnology 18:135706

76.

Iijima M, Kamiya H (2008) Surface modification of silicon carbide nanoparticles by azo radical initiators. J Phys Chem C 112:11786–11790

77.

Zou G, Cao M, Lin H, Jin H, Kang Y, Chen Y (2006) Nickel layer deposition on SiC nanoparticles by simple electroless plating and its dielectric behaviors. Powder Technol 168:84–88

78.

Puzder A, Williamson AJ, Grossman JC, Galli G (2002) Surface chemistry of silicon nanoclusters. Phys Rev Lett 88:097401

79.

Zhao X, Wei CM, Yang L, Chou MY (2004) Quantum confinement and electronic properties of silicon nanowires. Phys Rev Lett 92:236805

80.

Reboredo FA, Pizzagalli L, Galli G (2004) Computational engineering of the stability and optical gaps of SiC quantum dots. Nano Lett 4:801–804

81.

Peng X-H, Nayak SK, Alizadeh A, Varanasi KK, Bhate N, Rowland LB, Kumar SK (2007) First-principles study of the effects of polytype and size on energy gaps in SiC nanoclusters. J Appl Phys 102:024304

82.

Huda MN, Ray AK (2008) Evolution of SiC nanocluster from carbon fullerene: a density functional theoretic study. Chem Phys Lett 457:124–129

83.

Vörös M, Deák P, Frauenheim T, Gali A (2010) The absorption spectrum of hydrogenated silicon carbide nanocrystals from ab initio calculations. Appl Phys Lett 96:051909

84.

Fan J, Li H, Jiang J, So LKY, Lam YW, Chu PK (2008) 3C-SiC nanocrystals as fluorescent biological labels. Small 4:1058–1062

85.

Vörös M, Deák P, Frauenheim T, Gali A (2010) The absorption of oxygenated silicon carbide nanoparticles. J Chem Phys 133:064705

86.

Zhang Z, Dai Y, Yu L, Guo M, Huang B, Whangbo M-H (2012) The surface termination effect on the quantum confinement and electron affinities of 3C-SiC quantum dots: a first-principles study. Nanoscale 4:1592–1597

87.

Saha S, Sarkar P (2012) Tuning the HOMO-LUMO gap of SiC quantum dots by surface functionalization. Chem Phys Lett 536:118–122

88.

Zimmerman AF, Clark DG, Aust KT, Erb U (2002) Pulse electrodeposition of Ni-SiC nanocomposite. Mater Lett 52:85–90

89.

Zimmerman AF, Palumbo G, Aust KT, Erb U (2002) Mechanical properties of nickel silicon carbide nanocomposites. Mat Sci Eng A 328:137–146

90.

Shi L, Sun C, Gao P, Zhou F, Liu W (2006) Mechanical properties and wear and corrosion resistance of electrodeposited Ni-Co/SiC nanocomposite coating. Appl Surf Sci 252:3591–3599

91.

Vaezi MR, Sadrnezhaad SK, Nikzad L (2008) Electrodeposition of Ni-SiC nano-composite coatings and evaluation of wear and corrosion resistance and electroplating characteristics. Colloid Surf A 315:176–182

92.

Zhao J, Stearns LC, Harmer MP, Chan HM, Miller GA (1993) Mechanical behavior of alumina-silicon carbide “nanocomposites”. J Am Ceram Soc 76:503–510

93.

Ohji T, Nakahira A, Hirano T, Niihara K (1994) Tensile creep behavior of alumina/silicon carbide nanocomposite. J Am Ceram Soc 77:3259–3262

94.

Gao L, Wang HZ, Hong JS, Miyamoto H, Miyamoto K, Nishikawa Y, Torre SDDL (1999) Mechanical properties and microstructure of nano-SiC–Al₂O₃ composites densified by spark plasma sintering. J Eur Ceram Soc 19:609–613

95.

Yang Y, Lan J, Li X (2004) Study on bulk aluminum matrix nano-composite fabricated by ultrasonic dispersion of nano-sized SiC particles in molten aluminum alloy. Mat Sci Eng A 380:378–383

96.

Sawaguchi A, Toda K, Niihara K (1991) Mechanical and electrical properties of silicon nitride-silicon carbide nanocomposite material. J Am Ceram Soc 74:1142–1144

97.

Rendtel A, Hübner H, Herrmann M, Schubert C (1998) Silicon nitride/silicon carbide nanocomposite materials: II, hot strength, creep, and oxidation resistance. J Am Ceram Soc 81:1109–1120

98.

Ferkel H, Mordike BL (2001) Magnesium strengthened by SiC nanoparticles. Mat Sci Eng A 298:193–199

99.

Lan J, Yang Y, Li X (2004) Microstructure and microhardness of SiC nanoparticles reinforced magnesium composites fabricated by ultrasonic method. Mat Sci Eng A 386:284–290

100.

Chisholm N, Mahfuz H, Rangari VK, Ashfaq A, Jeelani S (2005) Fabrication and mechanical characterization of carbon/SiC-epoxy nanocomposites. Compos Struct 67:115–124

101.

Ma RZ, Wu J, Wei BQ, Liang J, Wu DH (1998) Processing and properties of carbon nanotubes-nano-SiC ceramic. J Mater Sci 33:5243–5246

102.

Dou SX, Soltanian S, Horvat J, Wang XL, Zhou SH, Ionescu M, Liu HK, Munroe P, Tomsic M (2002) Enhancement of the critical current density and flux pinning of MgB₂ superconductor by nanoparticle SiC doping. Appl Phys Lett 81:3419–3421

103.

Matsumoto A, Kumakura H, Kitaguchi H, Hatakeyama H (2003) Effect of SiO₂ and SiC doping on the powder-in-tube processed MgB₂ tapes. Supercond Sci Technol 16:926–930

104.

Matsumoto A, Kumakura H, Kitaguchi H, Senkowicz BJ, Jewell MC, Hellstrom EE, Zhu Y, Voyles PM, Larbalestier DC (2006) Evaluation of connectivity, flux pinning, and upper critical field contributions to the critical current density of bulk pure and SiC-alloyed MgB₂. Appl Phys Lett 89:132508

105.

Dou SX, Shcherbakova O, Yeoh WK, Kim JH, Soltanian S, Wang XL, Senatore C, Flukiger R, Dhalle M, Husnjak O, Babic E (2007) Mechanism of enhancement in electromagnetic properties of MgB₂ by nano SiC doping. Phys Rev Lett 98:097002

106.

Nienhaus H, Kampen TU, Mönch W (1995) Phonons in 3C-, 4H-, and 6H-SiC. Surf Sci 324:L328–L332

107.

Gall JL, Olivier M, Greffet J-J (1997) Experimental and theoretical study of reflection and coherent thermal emission by a SiC grating supporting a surface-phonon polariton. Phys Rev B 55:10105–10114

108.

Rockstuhl C, Salt MG, Herzig HP (2005) Analysis of the phonon-polariton response of silicon carbide microparticles and nanoparticles by use of the boundary element method. J Opt Soc Am B 22:481–487

109.

Neuner B III, Korobkin D, Fietz C, Carole D, Ferro G, Shvets G (2009) Critically coupled surface phonon-polariton excitation in silicon carbide. Opt Lett 34:2667–2669

110.

Neuner B III, Korobkin D, Fietz C, Carole D, Ferro G, Shvets G (2010) Midinfrared index sensing of pL-scale analytes based on surface phonon polaritons in silicon carbide. J Phys Chem C 114:7489–7491

111.

Kim HC, Cheng X (2010) Surface phonon polaritons on SiC substrate for surface-enhanced infrared absorption spectroscopy. J Opt Soc Am B 27:2393–2397

112.

Schuller JA, Zia R, Taubner T, Brongersma ML (2007) Dielectric metamaterials based on electric and magnetic resonances of silicon carbide particles. Phys Rev Lett 99:107401

113.

Francoeur M, Basu S, Petersen SJ (2011) Electric and magnetic surface polariton mediated near-field radiative heat transfer between metamaterials made of silicon carbide particles. Opt Express 19:18774–18788

114.

Nehmetallah G, Aylo R, Powers P, Sarangan A, Gao J, Li H, Achari A, Banerjee PP (2012) Co-sputtered SiC + Ag nanomixtures as visible wavelength negative index metamaterials. Opt Express 20:7095–7100

115.

Zhang N, Dai DJ, Fan JY (2012) Plasmon-assisted photoluminescence enhancement of SiC nanocrystals by proximal silver nanoparticles. Appl Surf Sci 258:10140–10143

116.

Dai D, Dong Z, Fan J (2013) Giant photoluminescence enhancement in SiC nanocrystals by resonant semiconductor exciton-metal surface plasmon coupling. Nanotechnology 24:025201

117.

Sui N, Monnier V, Zakharko Y, Chevolot Y, Alekseev S, Bluet J-M, Lysenko V, Souteyrand E (2012) Plasmon-controlled narrower and blue-shifted fluorescence emission in (Au@SiO₂)SiC nanohybrids. J Nanopart Res 14:1004

118.

Sui N, Monnier V, Zakharko Y, Chevolot Y, Alekseev S, Bluet J-M, Lysenko V, Souteyrand E (2013) Fluorescent (Au@SiO₂)SiC nanohybrids: influence of gold nanoparticle diameter and SiC nanoparticle surface density. Plasmonics 8:85–92

119.

Zakharko Y, Serdiuk T, Nychyporuk T, Géloën A, Lemiti M, Lysenko V (2012) Plasmon-enhanced photoluminescence of SiC quantum dots for cell imaging applications. Plasmonics 7:725–732

120.

Zakharko Y, Nychyporuk T, Bonacina L, Lemiti M, Lysenko V (2013) Plasmon-enhanced nonlinear optical properties of SiC nanoparticles. Nanotechnology 24:055703

121.

Fan J, Li H, Jiang J, So LKY, Lam YW, Chu PK (2008) 3C-SiC nanocrystals as fluorescent biological labels. Small 4:1058–1062

122.

Mimura H, Matsumoto T, Kanemitsu Y (1994) Blue electroluminescence from porous silicon carbide. Appl Phys Lett 65:3350–3352

123.

Xiao B, Wu XL, Xu W, Chu PK (2012) Tunable electroluminescence from polymer-passivated 3C-SiC quantum dot thin films. Appl Phys Lett 101:123110

124.

Tai H-Y, Cheng C-H, Lin G-R (2014) Blue-green light emission from Si and SiC quantum dots co-doped Si-rich SiC p-i-n junction diode. IEEE J Sel Top Quant Electron 20:8200507

125.

Xie H, Wang J, Xi T, Liu Y (2002) Thermal conductivity of suspensions containing nanosized SiC particles. Int J Thermophys 23:571–580

126.

Zhao L-D, Zhang B-P, Li J-F, Zhou M, Liu W-S, Liu J (2008) Thermoelectric and mechanical properties of nano-SiC-dispersed Bi₂Te₃ fabricated by mechanical alloying and spark plasma sintering. J Alloys Compd 455:259–264

127.

Mavinakuli P, Wei S, Wang Q, Karki AB, Dhage S, Wang Z, Young DP, Guo Z (2010) Polypyrrole/silicon carbide nanocomposites with tunable electrical conductivity. J Phys Chem C 114:3874–3882

128.

Zhao D-L, Luo F, Zhou W-C (2010) Microwave absorbing property and complex permittivity of nano SiC particles doped with nitrogen. J Alloys Compd 490:190–194

129.

He C, Wu X, Shen J, Chu PK (2012) High-efficiency electrochemical hydrogen evolution based on surface autocatalytic effect of ultrathin 3C-SiC nanocrystals. Nano Lett 12:1545–1548

130.

Shen X, Pantelides ST (2013) Atomic-scale mechanism of efficient hydrogen evolution at SiC nanocrystal electrodes. J Phys Chem Lett 4:100–104

Titel: Separate SiC Nanoparticles
verfasst von: Ji-Yang Fan
Paul Kim-Ho Chu
Verlag: Springer International Publishing
Buch: Silicon Carbide Nanostructures
Print ISBN: 978-3-319-08725-2

Electronic ISBN: 978-3-319-08726-9

Copyright-Jahr: 2014
DOI: https://doi.org/10.1007/978-3-319-08726-9_4

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Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

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