This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Cheng Z, Chaikin PM, Zhu J, Russel WB, Meyer WV (2002) Crystallization kinetics of hard spheres in microgravity in the coexistence regime: interactions between growing crystallites. Physical Review Letters88(1): 015501ChengZChaikinPMZhuJRusselWBMeyerWV2002Crystallization kinetics of hard spheres in microgravity in the coexistence regime: interactions between growing crystallitesPhysical Review Letters88101550110.1103/PhysRevLett.88.015501Search in Google Scholar
Cheng Z, Russell WB, Chaikin PM (1999) Controlled growth of hard-sphere colloidal crystals. Nature401: 893–895ChengZRussellWBChaikinPM1999Controlled growth of hard-sphere colloidal crystalsNature40189389510.1038/44785Search in Google Scholar
Clearfield A, Stynes JA (1964) The preparation of crystalline zirconium phosphate and some observations on its ion exchange behavior. Journal of Inorganic & Nuclear Chemistry26(1): 117–129ClearfieldAStynesJA1964The preparation of crystalline zirconium phosphate and some observations on its ion exchange behaviorJournal of Inorganic & Nuclear Chemistry26111712910.1016/0022-1902(64)80238-4Search in Google Scholar
He P, Mejia AF, Cheng Z, Sun D, Sue HJ, Dinair DS, Marquez M (2010) Hindrance function for sedimentation and creaming of colloidal disks. Physical Review E: Statistical, Nonlinear, and Soft Matter Physics81(2): 026310HePMejiaAFChengZSunDSueHJDinairDSMarquezM2010Hindrance function for sedimentation and creaming of colloidal disksPhysical Review E: Statistical, Nonlinear, and Soft Matter Physics81202631010.1103/PhysRevE.81.026310Search in Google Scholar
Kim H-N, Keller SW, Mallouk TE, Schmitt J, Decher G (1997) Characterization of zirconium phosphate/polycation thin films grown by sequential adsorption reactions. Chemistry of Materials9(6): 1414–1421KimH-NKellerSWMalloukTESchmittJDecherG1997Characterization of zirconium phosphate/polycation thin films grown by sequential adsorption reactionsChemistry of Materials961414142110.1021/cm970027qSearch in Google Scholar
Kleshchanok D, Holmqvist P, Meijer J-M, Lekkerkerker HNW (2012) Lyotropic smectic B phase formed in suspensions of charged colloidal platelets. Journal of the American Chemical Society134(13): 5985–5990KleshchanokDHolmqvistPMeijerJ-MLekkerkerkerHNW2012Lyotropic smectic B phase formed in suspensions of charged colloidal plateletsJournal of the American Chemical Society134135985599010.1021/ja300527wSearch in Google Scholar
Mejia AF, Chang Y-W, Ng R, Shuai M, Mannan MS, Cheng ZD (2012) Aspect ratio and polydispersity dependence of isotropicnematic transition in discotic suspensions. Physical Review E85(6): 061708MejiaAFChangY-WNgRShuaiMMannanMSChengZD2012Aspect ratio and polydispersity dependence of isotropicnematic transition in discotic suspensionsPhysical Review E85606170810.1103/PhysRevE.85.061708Search in Google Scholar
Odriozola G, Romero-Bastida M, Guevara-Rodriguez FJ (2004) Brownian dynamics simulations of laponite colloid suspensions. Physical Review E70(2): 021405OdriozolaGRomero-BastidaMGuevara-RodriguezFJ2004Brownian dynamics simulations of laponite colloid suspensionsPhysical Review E70202140510.1103/PhysRevE.70.021405Search in Google Scholar
Onsager L (1949) The effects of shape on the interaction of colloidal particles. Annals of the New York Academy of Sciences51(4): 627–659OnsagerL1949The effects of shape on the interaction of colloidal particlesAnnals of the New York Academy of Sciences51462765910.1201/9780203022658.ch4eSearch in Google Scholar
Shuai M, Mejia AF, Chang Y-W, Cheng Z (2013) Hydrothermal synthesis of layered alpha-zirconium phosphate disks: control of aspect ratio and polydispersity for nano-architecture. CrystEngComm15(10): 1970–1977ShuaiMMejiaAFChangY-WChengZ2013Hydrothermal synthesis of layered alpha-zirconium phosphate disks: control of aspect ratio and polydispersity for nano-architectureCrystEngComm15101970197710.1039/c2ce26402aSearch in Google Scholar
Sun D, Sue H-J, Cheng Z, Martinez-Raton Y, Velasco E (2009) Stable smectic phase in suspensions of polydisperse colloidal platelets with identical thickness. Physical Review E80(4): 041704SunDSueH-JChengZMartinez-RatonYVelascoE2009Stable smectic phase in suspensions of polydisperse colloidal platelets with identical thicknessPhysical Review E80404170410.1103/PhysRevE.80.041704Search in Google Scholar
van der Kooij FM, Kassapidou K, Lekkerkerker HNW (2000) Liquid crystal phase transitions in suspensions of polydisperse plate-like particles. Nature406: 868–871van der KooijFMKassapidouKLekkerkerkerHNW2000Liquid crystal phase transitions in suspensions of polydisperse plate-like particlesNature40686887110.1038/35022535Search in Google Scholar
Verhoeff AA, Bakelaar IA, Otten RHJ, van der Schoot P, Lekkerkerker HNW (2011) Tactoids of plate-like particles: size, shape, and director field. Langmuir27(1): 116–125VerhoeffAABakelaarIAOttenRHJvan der SchootPLekkerkerkerHNW2011Tactoids of plate-like particles: size, shape, and director fieldLangmuir27111612510.1021/la104128mSearch in Google Scholar
Xu Z, Gao C (2011) Graphene chiral liquid crystals and macroscopic assembled fibres. Nature Communications2: 571XuZGaoC2011Graphene chiral liquid crystals and macroscopic assembled fibresNature Communications257110.1038/ncomms1583Search in Google Scholar
Zhu J, Li M, Rogers R, Meyer W, Ottewill RH, Space Shuttle Crew STS-73, Russell WB, Chaikin PM (1997) Crystallization of hard-sphere colloids in microgravity. Nature387: 883–885ZhuJLiMRogersRMeyerWOttewillRHSpace Shuttle Crew STS-73RussellWBChaikinPM1997Crystallization of hard-sphere colloids in microgravityNature38788388510.1038/43141Search in Google Scholar
