[1] DONGRE J K, NOGRIYA V, RAMRAKHIANI M. Structural, optical and photoelectrochemical characterization of CdS nanowire synthesized by chemical bath deposition and wet chemical etching[J]. Applied surface science, 2009, 255(12):6115-6120.
[2] LAHARIYA V. Study of electroluminescence in cadmium sulfide polymer nanocomposite films[J]. Journal of nano research, 2017, 49:181-189.
[3] BANERJEE R, JAYAKRISHNAN R, AYYUB P. Effect of the size-induced structural transformation on the band gap in CdS nanoparticles[J]. Journal of physics: condensed matter, 2000, 12(50):10647-10652.
[4] NOGRIYA V, DONGRE J K, RAMRAKHIANI M, et al. Electro-and photo-luminescence studies of CdS nanocrystals prepared by organometallic precursor[J]. Chalcogenide letters, 2008, 5(12):365-373.
[5] LAHARIYA V, KUMARI E, SINGH N. Optical investigation of starch capped cadmium sulfide nanoparticles[J]. Materials today:proceedings, 2022, 48(3): 622-625.
[6] MALLIK K, MANDAL M, PRADHAN N, et al. Seed mediated formation of bimetallic nanoparticles by UV irradiation:a photochemical approach for the preparation of core-shell type structures[J]. Nano letters, 2001, 1(6):319-322.
[7] CELEBI S, ERDAMAR A K, SENNAROGLU A, et al. Synthesis and characterization of poly (acrylic acid) stabilized cadmium sulfide quantum dots[J]. Journal of physical chemistry B, 2007, 111:12668-12675.
[8] DEVI J, DUTTA P. A study on dielectric properties of cadmium-zinc sulphide core-shell nanocomposites for application as nanoelectronics filter component in microwave domain[J]. Journal of electronic materials, 2018, 47(7):3529-3542.
[9] SUTHAKARAN S, DHANAPANDIAN S, KRISHNAKUMAR N, et al. Hydrothermal synthesis of surfactant assisted Zn doped SnO2 nanoparticles with enhanced photocatalytic performance and energy storage performance[J]. Journal of physics and chemistry of solids, 2020, 141:109407.
[10] LAHARIYA V, RAMRAKHIANI M. Luminescence study on Mn, Ni co-doped zinc sulfide nanocrystals[J]. Luminescence, 2020, 35(6):924-933.
[11] AMMA B S, RAMAKRISHNA K, PATTABI M. Comparison of various organic stabilizers as capping agents for CdS nanoparticles synthesis[J]. Journal of materials science: materials in electronics, 2007, 18(11):1109-1113.
[12] SADHU S, CHOWDHURY P S, PATRA A. Synthesis, and time-resolved photoluminescence spectroscopy of capped CdS nanocrystals[J]. Journal of luminescence, 2008, 128(7):1235-1240.
[13] LAHARIYA V, KUMAR S. Study on structural and optical properties of Sb2S3 and CdI2 composite thin films deposited by thermal vapor deposition[J]. International journal of nanoscience, 2018, 17(04):1760033.
[14] MURUGADOSS G. Synthesis and optical characterization of PVP and SHMP-encapsulated Mn2+-doped ZnS nanocrystals[J]. Journal of luminescence, 2010, 130(11):2207-2214.
[15] WARAD H C, GHOSH S C, HEMTANON B, et al. Luminescent nanoparticles of Mn doped ZnS passivated with sodium hexametaphosphate[J]. Science and technology of advanced materials, 2005, 6(3-4):296-301.
[16] THAKUR S, DAS P, MANDAL S K. Solvent-induced diversification of CdS nanostructures for photocatalytic degradation of methylene blue[J]. ACS applied nano materials, 2020, 3(6):5645-5655.
[17] MARANDI M, TAGHAVINIA N, MAHDAVI S M. A photochemical method for controlling the size of CdS nanoparticles[J]. Nanotechnology, 2005, 16 (2):334.
[18] LOZADA-MORALES R, ZELAYA-ANGEL O, TORRES-DELGADO G. Photoluminescence in cubic and hexagonal CdS films[J]. Applied surface science, 2001, 175:562-566.
[19] WAGEH S, SHU-MAN L, YOU F T, et al. Optical properties of strongly luminescing mercaptoactic-acid-capped ZnS nanoparticles[J]. Journal of luminescence, 2003, 102:768-773.
[20] KUMAR S, GRADZIELSKI M, MEHTA S K. The critical role of surfactants towards CdS nanoparticles: synthesis, stability, optical and PL emission properties[J]. RSC advances, 2013, 3(8):2662-2676.
[21] MCCAMY C S. Correlated color temperature as an explicit function of chromaticity coordinates[J]. Color research & application, 1992, 17(2):142-144.
[22] KOCZKUR K M, MOURDIKOUDIS S, POLAVARAPU L, et al. Polyvinylpyrrolidone (PVP) in nanoparticle synthesis[J]. Dalton transactions, 2015, 44(41): 17883-17905.
[23] LU J, SUN M, YUAN Z, et al. Innovative insight for sodium hexametaphosphate interaction with serpentine[J]. Colloids and surfaces A:physicochemical and engineering aspects, 2019, 560:35-41.
[24] LI Z H, HAN Y X, LI Y J, et al. Effect of serpentine and sodium hexametaphosphate on ascharite flotation[J]. Transactions of nonferrous metals society of China, 2017, 27(8):1841-1848.