References
- Ramachandran E, Natarajan S, Ramachandran E, et al. Crystal growth of some urinary stone constituents: III. in‐vitro crystallization of L‐cystine and its characterization”. Cryst Res Technol. 2004;39:308–312.
- Rajesh K, Mani A, Thayanithi V, et al. Optical, thermal, and mechanical properties of l-serine phosphate, a semiorganic enhanced NLO single crystal. Int J Opt. 2016;9070714:1–5.
- Zyss J, Nicoud JF, Coquillay M. Chirality and hydrogen bonding in molecular crystals for phase‐matched second‐harmonic generation: N‐(4‐nitrophenyl)‐(L)‐prolinol (NPP). J Chem Phys. 1984;81:4160.
- Rheingold AL. CCDC 844328 Experimental crystal structure determination; 2014. DOI:10.5517/ccxbld6
- Rajesh K, Mani A, Anandan K, et al. Crystal and optical perfection, linear and nonlinear optical qualities of β alanine β alaninium picrate (βAβAP) single crystal: a promising NLO crystal for optics and photonics applications. J Mater Sci. 2017;28(15):11446–11454.
- Van Schalkwyk TGD. The crystal structure of Phthalic acid. ActaCryst. 1954;7:775.
- Colthup NB, Daly LH, Wiberley SE. Introduction toInfrared and Raman spectroscopy. third ed. San Diego, CA: Academic press Inc; 1990.
- Pichevin Peltier. Dizabo and josien, Compt. Rend. Acad. Sci. Paris. 1959;248:1148.
- Suresh Kumar M, Krishnan S, Das J. Growth, optical and thermal studies on novel nonlinear optical crystal: glycine–phthalic acid (GPA). Optik. 2016;127:2509–2511.
- Anie Roshan A, Joseph C, Ittyachan MA. Growth and characterization of a new metal-organic crystal: potassium thiourea bromide. Mater Lett. 2001;49:299.
- Hanumantharao R, Kalainathan S. Growth and spectroscopic investigation of a new crystal for NLO applications: C10H20KN5O9. Spectrochim Acta A. 2012;99:181–188.
- Santhakumari P, Ramamurthi K. Structural, thermal and optical characterization of an organic NLO material—benzaldehyde thiosemicarbazone monohydrate single crystals. Spectrochim Acta Part A. 2011;78:653–659.
- Hanumantharao R, Kalainathan S, Bhagavannarayana G, et al. An extensive investigation on nucleation, growth parameters, crystalline perfection, spectroscopy, thermal, optical, microhardness, dielectric and SHG studies on potential NLO crystal – ammonium hydrogen l-tartarte. Spectrochim Acta A. 2013;103:388–399.
- Kurtz SK, Perry TT. A powder technique for the evaluation of nonlinear optical materials. J Appl Phys. 1968;39:3798.
- Hou WB, Yuan ZH, Xu D, et al. Thermal properties of a new organometallic nonlinear optical material-triallylthiourea mercury bromide (ATMB). Mater Lett. 1994;18:207–210.
- Ramesh Babu R, Sethuraman K, Vijayan N, et al. Characterization of melt grown phthalic anhydride single crystal. Cryst Res Technol. 2008;43(1):50–54.
- Coats AV, Redfern JP. Kinetic parameters from thermogravimetric data. J Nature. 1964;210:68–69.
- Dalal PV, Saraf KB, Shimpi NG, et al. Pyro and kinetic studies of barium oxalate crystals grown in agar gel. J Cryst Process Technol. 2012;2:156–160.
- Yakuphanoglu F, Gorgulu AO, Cukurovali A, et al. An organic semiconductor and conduction mechanism: N-[5-methyl-1,3,4-tiyodiazole-2-yl] ditiyocarbamate compound. Phys B Condens Matter. 2004;353(3–4):223–229.
- Mallakpour S, Dinari M. Eco-friendly fast synthesis and thermal degradation of optically active polyamides under microwave accelerating conditions. Chin J Polym Sci. 2010;28(5):685–694.
- Bera J, Sarkar D. Formation of BaTiO3 from barium oxalate and TiO2. J Electroceram. 2003;11(3):131–137.
- Arora SK, Patel V, Amin B, et al. Dielectric behaviour of strontium tartrate single crystals. Bull Mater Sci. 2004;27:141–147.
- Smyth CP. Dielectric behaviour and structure. New York: McGraw Hill; 1965. p. 132.
- Von Hundelshausen U. Electrooptic effect and dielectric properties of cadmium-mercury- thiocyanate crystals. Phys Lett A. 1971;34:405–406.
- Rao KV, Smakula A. Dielectric properties of alkaline earth fluoride single crystals. J Appl Phys. 1965;36:2031–2038.
- Balarew C, Dehlew R. Application of the hard and soft acids and bases concept to explain ligand coordination in double salt structures. J Solid State Chem. 1984;55(1):1–6.