[1] F LIU, K F CHEN, C PENG et al. Advance in theory and technology of rapid growth of large-size crystals. Journal of Synthetic Crystals, 51:, 1732(2022).
[4] CHEN KUNFENG, WU JI’AN, HU QIAN’YU et al. Omni-functional crystal: advanced methods to characterize the composition and homogeneity of lithium niobate melts and crystals. Exploration(2022).
[5] K F CHEN, D F XUE. Fast growth of cerium-doped lutetium yttrium orthosilicate single crystals and their scintillation properties. Journal of Rare Earths, 1527(2021).
[6] J ZHAO, DJ MEI, DF XUE et al. Recent advances in nonlinear optical rare earth structures. Journal of Rare Earths, 1455(2021).
[8] F LIU, KF CHEN, C PENG et al. Recent advances and perspectives on melt structures of large-size functional oxcide crystals. Journal of the Chinese Ceramic Society(2023).
[9] C SUN, D XUE. Chemical bonding theory of single crystal growth and its application to fast single crystal growth of rare earth inorganic materials. Science China Chemistry, 804(2018).
[10] D K ASWAL, M SHINMURA, Y HAYAKAWA et al. In situ observation of melting/dissolution, nucleation and growth of NdBa2Cu3Ox by high temperature optical microscopy. Journal of Crystal Growth, 61(1998).
[11] D K ASWAL, M SHINMURA, Y HAYAKAWA et al. In situ measurement of the growth rate of YBa2Cu3Ox single crystals. Journal of Crystal Growth, 379(1999).
[12] I SOHN, R DIPPENAAR. In-situ observation of crystallization and growth in high-temperature melts using the confocal laser microscope. Metallurgical and Materials Transactions B, 47B:, 2083(2016).
[13] Y HOMMA. 23-In Situ Observation of Crystal Growth by Scanning Electron Microscopy. Handbook of Crystal Growth (2nd Edition) Fundamentals, 1003-1030(2015).
[14] Z ZHANG, L FEI, Z RAO et al. In situ observation of ice formation from water vapor by environmental SEM. Crystal Growth Design, 18:, 6602(2018).
[15] Z ZHANG, N S LIU, L Y LI et al. In situ TEM observation of crystal structure transformation in InAs nanowires on atomic scale. Nano Letters, 6597(2018).
[16] J LI, F L DEEPAK. In situ kinetic observations on crystal nucleation and growth. Chemical Review, 122:, 16911(2022).
[17] H NISHIZAWA, F HORI, R OSHIMA. In-situ HRTEM observation of the melting-crystallization process of silicon. Journal of Crystal Growth, 236:, 51(2002).
[18] A MCPHERSON, A J MALKIN, Y G KUZNETSOV. Atomic force microscopy in the study of macromolecular crystal growth. Annual Review of Biophysics and Biomolecular Structure, 29:, 361(2000).
[19] M J KRASINSKI, R ROLANDI. Ex situ investigation of surface topography of as-grown potassium dihydrogen phosphate crystals by atomic force microscopy. Journal of Crystal Growth, 548(1996).
[20] S F YANG, G B SU, J TANG et al. Surface topography of rapidly grown KH2PO4 crystals with additives: ex situ investigation by atomic force microscopy. Journal of Crystal Growth, 425(1999).
[21] L LIU, S ZHANG, M E BOWDEN et al. In situ TEM and AFM investigation of morphological controls during the growth of single crystal BaWO4. Crystal Growth & Design, 18:, 1367(2018).
[22] T PETIT, L PUSKAR. FTIR spectroscopy of nanodiamonds: methods and interpretation. Diamond and Related Materials, 89:, 52(2018).
[23] G R ALCOTT, MOL T VAN, K SPEE. Evaluation of chemometric models in an FTIR study of the gas phase during atmospheric- pressure CVD of tin oxide thin films. Chemical Vapor Deposition, 261(2000).
[24] D D DUNUWILA, K A BERGLUND. ATR FTIR spectroscopy for in situ measurement of supersaturation. Journal of Crystal Growth, 185(1997).
[25] C T SUN, D F XUE. In situ IR spectral identification of NH4H2PO4 structural evolution during crystallization in water-ethanol mixed solvent. CrystEngComm, 2728(2015).
[26] C T SUN, D F XUE. In situ IR spectral observation of NH4H2PO4 crystallization: structural identification of nucleation and crystal growth. Journal of Physical Chemistry C, 19146(2013).
[27] C T SUN, D F XUE. Hydrogen bonding nature during ADP crystallization. Journal of Molecular Structure, 1059:, 338(2014).
[28] C T SUN, D F XUE. Crystallization behaviors of KDP and ADP. Optical Materials, 1966(2014).
[29] C T SUN, D F XUE. In situ ATR-IR observation of nucleation and crystal growth of KH2PO4 in aqueous solution. CrystEngComm, 10445(2013).
[30] M CHENG, S T SUN, P Y WU. Microdynamic changes of moisture- induced crystallization of amorphous calcium carbonate revealed via in situ FTIR spectroscopy. Physical Chemistry Chemical Physics, 21882(2019).
[31] M MASLYK, M MONDESHKI, W TREMEL. Amorphous calcium carbonate monohydrate containing a defect hydrate network by mechanochemical processing of mono-hydrocalcite using ethanol as auxiliary solvent. CrystEngComm, 4687(2022).
[32] P W MORRISON, J R HAIGIS. In situ infrared measurements of film and gas properties during the plasma deposition of amorphous hydrogenated silicon. Journal of Vacuum Science & Technology A, 490(1993).
[33] S JONAS, W S PTAK, W SADOWSKI et al. FTIR in-situ studies of the gas-phase reactions in chemical-vapor-deposition of SiC. Journal of the Electrochemical Society, 2357(1995).
[34] D WANG, S M WAN, S T YIN et al. High temperature Raman spectroscopy study on the microstructure of the boundary layer around a growing LiB3O5 crystal. Crystengcomm, 5239(2011).
[35] H O YANG, J H KIM, K J KIM. Study on the crystallization rates of beta- and epsilon-form HNIW in in-situ Raman spectroscopy and FBRM. Propellants Explosives Pyrotechnics, 422(2020).
[36] J ZHANG, D WANG, D M ZHANG et al. In situ investigation of BaBPO5 crystal growth mechanism by high-temperature Raman spectroscopy. Journal of Molecular Structure, 1138:, 50(2017).
[37] X H ZHANG, H S LUO, W Z ZHONG. The analysis of morphology evolution in KABO crystal growth. Journal of Crystal Growth, 104(2006).
[38] S S LIU, G C ZHANG, K FENG et al. In situ Raman spectroscopy studies on La2CaB10O19 crystal growth. Crystal Growth & Design, 6604(2020).
[39] C T SUM, X Y CHEN, D F XUE. Hydrogen bonding dependent mesoscale framework in crystalline Ln(H2O)9(CF3SO3)3. Crystal Growth & Design, 2631(2017).
[40] N ZHANG, Z LIN, S MAN. Fabrication and spectral properties of Tm3+-doped novel bismuthate glasses. Journal of the Chinese Society of Rare Earths, 54(2022).
[41] J CORNEL, M MAZZOTTI. Estimating crystal growth rates using in situ ATR-FTIR and Raman spectroscopy in a calibration-free manner. Industrial & Engineering Chemistry Research, 10740(2009).
[42] X Y CHEN, C T SUN, S X WU et al. Molecular paradigm dependent nucleation in urea aqueous solution. Crystal Growth & Design, 2594(2017).
[43] X Y CHEN, C T SUN, S X WU et al. Nucleation-dependant chemical bonding paradigm: the effect of rare earth ions on the nucleation of urea in aqueous solution. Physical Chemistry Chemical Physics, 8835(2017).
[44] C T SUN, D F XUE. Physical chemistry of crystalline (K,NH4)H2PO4 in aqueous solution: an in situ molecule vibration spectral observation of the early formation stage. Journal of Physical Chemistry C, 16043(2014).
[45] Y P ZHANG, D F XUE. In-situ micro-Raman spectroscopy study of gypsum crystallization driven by chemical reaction. Journal of Molecular Structure, 1210:, 128043(2020).
[46] N PIENACK, W BENSCH. In-situ monitoring of the formation of crystalline solids. Angewandte Chemie International Edition, 2014(2011).
[47] R FORKER, T FRITZ. Optical differential reflectance spectroscopy of ultrathin epitaxial organic films. Physical Chemistry Chemical Physics, 2142(2009).
[48] H PROEHL, R NITSCHE, T DIENEL et al. In situ differential reflectance spectroscopy of thin crystalline films of PTCDA on different substrates. Physical Review B, 165207(2005).
[49] L ZHANG, C G HU, X FU et al. Pentacene crystal transition during the growth on SiO2 studied by in situ optical spectroscopy. Synthetic Metals, 231:, 65(2017).
[50] L ZHANG, X FU, M HOHAGE et al. Growth of pentacene on alpha-Al2O3(0001) studied by in situ optical spectroscopy. Physical Review Materials, 043401(2017).
[51] Y N WANG, L ZHANG, C H SU et al. Direct observation of monolayer MoS2 prepared by CVD using in-situ differential reflectance spectroscopy. Nanomaterials, 1640(2019).
[52] J S O EVANS, S J PRICE, H V WONG et al. Kinetic study of the intercalation of cobaltocene by layered metal dichalcogenides with time-resolved in situ X-ray powder diffraction. Journal of the American Chemical Society, 10837(1998).
[53] A M BEALE, G SANKAR. In situ study of the formation of crystalline bismuth molybdate materials under hydrothermal conditions. Chemistry of Materials, 146(2003).
[54] Y ZHOU, E ANTONOVA, W BENSCH et al. In situ X-ray diffraction study of the hydrothermal crystallization of hierarchical Bi2WO6 nanostructures. Nanoscale, 2412(2010).
[55] H A MA, X JIA, Q L CUI et al. Crystal structures of C3N6H6 under high pressure. Chemical Physics Letters, 668(2003).
[56] R KIEBACH, N PIENACK, M E ORDOLFF et al. Combined in situ EDXRD/EXAFS investigation of the crystal growth of [Co(C6H18N4)][Sb2S4] under solvothermal conditions: two different reaction pathways leading to the same product. Chemistry of Materials, 1196(2006).
[57] D E SAYERS, E A STERN, F W LYTLE. New technique for investigating noncrystalline structures-Fourier analysis of extended X-ray-absorption fine structure. Physical Review Letters, 1204(1971).
[58] K TAMURA, H OYANAGI, T KONDO et al. Structural study of electrochemically deposited Cu on p-GaAs(100) in H2SO4 solution by in situ surface-sensitive X-ray absorption fine structure measurements. Journal of Physical Chemistry B, 9017(2000).
[59] F F MUNOZ, L M ACUNA, C A ALBORNOZ et al. Redox properties of nanostructured lanthanide-doped ceria spheres prepared by microwave assisted hydrothermal homogeneous co-precipitation. Nanoscale, 271(2015).
[60] Y Z TANG, E J ELZINGA, Y J LEE et al. Coprecipitation of chromate with calcite: batch experiments and X-ray absorption spectroscopy. Geochimica et Cosmochimica Acta, 1480(2007).
[61] Y ZHANG, H Y WANG, C Q MA et al. Growth and optical properties of gray-track-resistant KTiOPO4 single crystals. Journal of Crystal Growth, 412:, 67(2015).
[62] T YAO, Z H SUN, Y Y LI et al. Insights into initial kinetic nucleation of gold nanocrystals. Journal of the American Chemical Society, 7696(2010).
[63] J MORELL, C V TEIXEIRA, M CORNELIUS et al. In situ synchrotron SAXS/XRD study on the formation of ordered mesoscopic hybrid materials with crystal-like walls. Chemistry of Materials, 5564(2004).
[64] Y DU, K M OK, D O'HARE. A kinetic study of the phase conversion of layered cobalt hydroxides. Journal of Materials Chemistry, 4450(2008).
[65] P BOTS, L G BENNING, J D RODRIGUEZ-BLANCO et al. Mechanistic insights into the crystallization of amorphous calcium carbonate (ACC). Crystal Growth & Design, 3806(2012).
[66] C B ZHOU, H F LI, W Y ZHANG et al. Direct investigations on strain-induced cold crystallization behavior and structure evolutions in amorphous poly(lactic acid) with SAXS and WAXS measurements. Polymer, 90:, 111(2016).
[67] J CRAVILLON, C A SCHRODER, R NAYUK et al. Fast nucleation and growth of ZIF-8 nanocrystals monitored by time-resolved in situ small-angle and wide-angle X-ray scattering. Angewandte Chemie International Edition, 8067(2011).
[68] W FAN, M OGURA, G SANKAR et al. In situ small-angle and wide-angle X-ray scattering investigation on nucleation and crystal growth of nanosized zeolite A. Chemistry of Materials, 1906(2007).
[69] M BREMHOLM, M FELICISSIMO, B B IVERSEN. Time-resolved in situ synchrotron X-ray study and large-scale production of magnetite nanoparticles in supercritical water. Angewandte Chemie International Edition, 4788(2009).
[70] A K CHEETHAM, C F MELLOT. In situ studies of the Sol-Gel synthesis of materials. Chemistry of Materials, 2269(1997).
[71] H W WANG, D J WESOLOWSKI, T E PROFFEN et al. Structure and stability of SnO2 nanocrystals and surface-bound water species. Journal of the American Chemical Society, 6885(2013).
[72] C FERNANDEZ-MARTIN, G BRUNO, A CROCHET et al. Nucleation and growth of nanocrystals in glass-ceramics: an in situ SANS perspective. Journal of the American Ceramic Society, 1304(2012).
[73] R I WALTON, F MILLANGE, R I SMITH et al. Real time observation of the hydrothermal crystallization of barium titanate using in situ neutron powder diffraction. Journal of the American Chemical Society, 12547(2001).
[74] J M GAINES, C PONZONI. An in-situ characterization of II-VI molecular-beam epitaxy. Physica Status Solidi B-Basic Research, 309(1995).
[75] J SENKER, J SEHNERT, S CORRELL. Microscopic description of the polyamorphic phases of triphenyl phosphite by means of multidimensional solid-state NMR Spectroscopy. Journal of the American Chemical Society, 337(2005).
[76] Y Z ZHU, J L DING, W J WANG et al. Interface diagnostics: in-situ determination of crystal-melt interface shape evolutions via probing growth interface electromotive force. Acta Materialia, 238:, 118242(2022).
[77] D GRANDJEAN, A M BEALE, A V PETUKHOV et al. Unraveling the crystallization mechanism of CoAPO-5 molecular sieves under hydrothermal conditions. Journal of the American Chemical Society, 14454(2005).
[79] L SKUBIC, J SOVDAT, N TERAN et al. Ab initio multiscale process modeling of ethane, propane and butane dehydrogenation reactions: a review. Catalysts, 1405(2020).
[80] R M MARTIN. Electronic Structure:Basic Theory and Practical Methods. Cambridge University Press(2020).
[81] C FREYSOLDT, B GRABOWSKI, T HICKEL et al. First-principles calculations for point defects in solids. Reviews of Modern Physics, 253(2014).
[82] K CHEN, Y LI, C PENG et al. Microstructure and defect characteristics of lithium niobate with different Li concentrations. Inorganic Chemistry Frontiers, 4006(2021).
[83] H WANG, J S TSE, K TANAKA et al. Superconductive sodalite- like clathrate calcium hydride at high pressures. Proceedings of the National Academy of Sciences, 6463(2012).
[84] S B ZHANG, S H WEI, ZUNGER. A intrinsic n-type versus p-type doping asymmetry and the defect physics of ZnO. Physical Review B, 075205(2001).
[85] A JANOTTI, C G VAN DE WALLE. Oxygen vacancies in ZnO. Applied Physics Letters, 122102(2005).
[86] A JANOTTI, C G VAN DE WALLE. Native point defects in ZnO. Physical Review B, 165202(2007).
[87] D FRENKEL, B SMIT, M A RATNER. Understanding Molecular Simulation:from Algorithms to Applications. Academic Press San Diego(1996).
[88] M P ALLEN, D J TILDESLEY. Computer Simulation of Liquids(2017).
[89] A BAUMGÄRTNER, K BINDER, J P HANSEN et al. Applications of the Monte Carlo method in statistical physics. Springer Science & Business Media(2013).
[90] M BORN, H S GREEN. A General Kinetic Theory of Liquids. CUP Archive(1949).
[91] J Q BROUGHTON, G H GILMER, K A JACKSON. Crystallization rates of a Lennard-Jones liquid. Physical Review Letters, 1496(1982).
[92] G SUN, J XU, P HARROWELL. The mechanism of the ultrafast crystal growth of pure metals from their melts. Nature Materials, 881(2018).
[93] Q GAO, J D AI, S X TANG et al. Fast crystal growth at ultra-low temperatures. Nature Materials, 1431(2021).
[94] F DING, B I YAKOBSON. Energy-driven kinetic Monte Carlo method and its application in fullerene coalescence. The Journal of Physical Chemistry Letters, 2922(2014).
[95] L D LANDAU, E M LIFSHITZ. Course of Theoretical Physics. Elsevier(2013).
[96] Z HONG, V VISWANATHAN. Phase-field simulations of lithium dendrite growth with open-source software. ACS Energy Letters, 1737(2018).
[97] T GONG, Y CHEN, S LI et al. Revisiting dynamics and models of microsegregation during polycrystalline solidification of binary alloy. Journal of Materials Science & Technology, 74:, 155(2021).
[98] H H LEE. Finite Element Simulations with ANSYS Workbench 2022: Theory, Applications, Case Studies. SDC Publications(2022).
[99] A LIPCHIN, R A BROWN. Hybrid finite-volume/finite-element simulation of heat transfer and melt turbulence in Czochralski crystal growth of silicon. Journal of Crystal Growth, 192(2000).
