[1] L CHEN, J FENG. Research status and application of silicon nitride ceramic materials. Journal of Cemented Carbide, 19, 26-229(2002).
[2] T XIE, C WU Y, D ZHANG L. Synthesis and photoluminescence of single-crystalline α-Si3N4 nanowires. Journal of Functional Materials, 35, 3027-3029(2004).
[3] Y JING G, H JI, Y YANG W et al. Study of the bending modulus of individual silicon nitride nano-belts via atomic force microscopy. Applied Physics A, 82, 475-478(2006).
[4] G MAIRE, L VIVIEN, G SATTLE et al. High efficiency silicon nitride surface grating couplers. Optics Express, 16, 328-333(2008).
[5] J HUANG, Z HUANG, S YI et al. Fe-catalyzed growth of one-dimensional α-Si3N4 nanostructures and >their cathodoluminescence properties. Scientific Reports, 3(2013).
[6] Y GU, L LU, H ZHANG et al. Nitridation of silicon powders catalyzed by cobalt nanoparticles. Journal of the American Ceramic Society, 98, 1762-1768(2015).
[7] F WANG, J HAO Y, Q QIN G et al. Effects of the reaction conditions in preparation of Si3N4 nanowires. Acta Physico-Chimica Sinica, 23, 1503-1507(2007).
[8] K LI, K ZHAO, Y WANG. In-situ synthesis and growth mechanism of silicon nitride nanowires on carbon fiber fabrics. Ceramics International, 40, 15381-15389(2014).
[9] F GUO G, W LI X, W FENG et al. Pyrolytic synthesis of single- crystal Si3N4 nanowires by polymeric precursor. Rare Metal Materials and Engineering, 38, 967-969(2009).
[10] Z RAN G, P YOU L, L DAI et al. Catalystless synthesis of crystalline Si3N4/amorphous SiO2 nanocables from silicon substrates and N2. Chemical Physics Letters, 384, 94-97(2004).
[11] F WANG, Q JIN G, Y GUO X. Formation mechanism of Si3N4 nanowires via carbothermal reduction of carbonaceous silica xerogels. Journal of Physical Chemistry B, 110, 14546-14549(2006).
[12] L DU H, W ZHANG, Y LI. Effects of growth parameters on the yield and morphology of Si3N4 microcoil prepared by chemical vapor deposition. Materials Research Bulletin, 50, 57-62(2014).
[13] J HUANG, S ZHANG, Z HUANG et al. Catalyst-assisted synthesis and growth mechanism of ultra-long single crystal α-Si3N4 nanobelts with strong violet-blue luminescent properties. CrystEngComm, 14, 7301-7305(2012).
[14] A RODRIGUEZ M, S MAKHONIN N, A ESCRINA J et al. Single crystal β-Si3N4 fibers obtained by self-propagating high temperature synthesis. Advanced Materials, 7, 745-747(1995).
[15] G CAO Y, C GE C, J ZHOU Z et al. Combustion synthesis of α-Si3N4 whiskers. Journal of Materials Research, 14, 876-880(1999).
[17] M YUAN C, C LI, G LI. Kinetic parameters of maize starch in nitrogen atmosphere. Journal of Northeastern University Natural Science, 33, 584-587(2012).
[18] R CYPRES, M GHODSI, P LEMPEREUR J. Direct hydrogenation of carbons by isothermal microthermogravimetry at atmospheric pressure. Fuel Process Technol, 2, 171-178(1979).
[19] Z LI, W GAO, A MENG et al. Large-scale synthesis and Raman and photoluminescence properties of single crystalline β-SiC nanowires periodically wrapped by amorphous SiO2 nanospheres. Journal of Physical Chemistry C, 113, 91-96(2009).
[20] H LIU, Z HUANG, J HUANG et al. Novel, low-cost solid-liquid- solid process for the synthesis of α-Si3N4 nanowires at lower temperatures and their luminescence properties. Scientific Reports, 5(2015).
[22] F WANG, Q JIN G, Y GUO X. Sol-Gel synthesis of Si3N4 nanowires and nanotubes. Materials Letters, 60, 330-333(2006).