Low temperature heat capacities and thermodynamic properties of rare earth triisothiocyanate hydrates——Pr(NCS)3· 7H2O and Nd(NCS)3· 7H2O

被引:0
|
作者
谭志诚
Matsuo Takasuke
Suga Hiroshi
张志英
尹敬执
蒋本杲
孙同山
机构
[1] Thermochemistry Laboratory
[2] China
[3] Xi’ an 710069
[4] Department of Chemistry
[5] Jinan 250100
[6] Chinese Academy of Sciences
[7] Dalian 116023
[8] Microcalorimetry Research Center
[9] Japan
[10] Northwestern University
[11] Faculty of Scienoes
[12] Osaka 560
[13] Osaka University
[14] Shandong University
[15] Dalian Institute of Chemical Physics
[16] Toyonaka
来源
Science in China,SerB | 1996年 / Ser.B1996卷 / 03期
基金
中国国家自然科学基金;
关键词
heat capacity; thermodynamic functions; rare earth; Pr(NCS)3·7H2O; Nd(NCS)3·7H2O;
D O I
暂无
中图分类号
O642 [化学热力学、热化学、热力学平衡];
学科分类号
070304 ; 081704 ;
摘要
Heat capacities of Pr(NCS)3·7H2O and Nd(NCS)3· 7H2O haw been measured from 13 to 300 K by using a fully automated adiabatic calorimeter. Schottky anomaly was observed for Pr(NCS)3·7H2O below 50 K. The polynomial equations for calculating the heat capacity values of the two compounds in the range of 13-300 K were obtained by the least-squares fitting based on the experimental Cp data. The Cp values below 13 K were estimated by using the Debye-Einstein and Schottky heat capacity functions. The standard molar thermodynamic functions were computed from 0 to 300 K. The standard entropies and Gibbs energies of formation of the two compounds were also calculated.
引用
收藏
页码:276 / 284
页数:9
相关论文
共 50 条
  • [31] Low temperature heat capacity study of Co3(BTC)2•12H2O and Ni3(BTC)2•12H2O
    Li, Rongchun
    Luo, Jipeng
    Yan, Huimin
    Zheng, Hui
    Wei, Rongmin
    Yang, Min
    Gu, Xiangling
    Tan, Zhicheng
    Shi, Quan
    THERMOCHIMICA ACTA, 2021, 699
  • [32] Thermodynamic properties of the NaNO3+H2O system
    Archer, DG
    JOURNAL OF PHYSICAL AND CHEMICAL REFERENCE DATA, 2000, 29 (05) : 1141 - 1156
  • [33] Low temperature heat capacity study of Fe3PO7 and Fe4(P2O7)3
    Shi, Quan
    Zhang, Liying
    Schlesinger, Mark E.
    Boerio-Goates, Juliana
    Woodfield, Brian F.
    JOURNAL OF CHEMICAL THERMODYNAMICS, 2013, 62 : 86 - 91
  • [34] Heat capacity and thermodynamic properties of 2,4-dichlorobenzaldehyde (C7H4Cl2O)
    Wang, SX
    Tan, ZC
    Di, YY
    Xu, F
    Zhang, HT
    Sun, LX
    Zhang, T
    JOURNAL OF CHEMICAL THERMODYNAMICS, 2004, 36 (05) : 393 - 399
  • [35] Low-temperature properties of magnetically frustrated rare-earth zirconates A 2Zr2O7
    Vojtasova, D.
    Stasko, D.
    Hajek, F.
    Colman, R. H.
    Klicpera, M.
    JOURNAL OF PHYSICS-CONDENSED MATTER, 2024, 36 (32)
  • [36] Low-temperature heat capacity of Ir(C5H7O2)(C8H12)
    Bespyatov, M. A.
    Kuzin, T. M.
    Naumov, V. N.
    Vikulova, E. S.
    Ilyin, I. Yu.
    Morozova, N. B.
    Gelfond, N. V.
    JOURNAL OF CHEMICAL THERMODYNAMICS, 2016, 99 : 70 - 74
  • [37] Redetermination of low-temperature heat capacity of Cu(C5H7O2)
    Bespyatov, M. A.
    JOURNAL OF CHEMICAL THERMODYNAMICS, 2019, 137 : 1 - 6
  • [38] Low-temperature heat capacity of Al(C11H19O2)3
    Bespyatov, Michael A.
    Chernyaikin, Ivan S.
    Naumov, Viktor N.
    Stabnikov, Pavel A.
    Gelfond, Nikolay V.
    THERMOCHIMICA ACTA, 2014, 596 : 40 - 41
  • [39] Thermodynamic and spectroscopic properties of Co7/3Sb2/3O4
    Knyazev, A. V.
    Smirnova, N. N.
    Maczka, M.
    Hermanowicz, K.
    Knyazeva, S. S.
    Letyanina, I. A.
    Lelet, M. I.
    JOURNAL OF CHEMICAL THERMODYNAMICS, 2014, 74 : 201 - 208
  • [40] High-temperature heat capacity and thermodynamic properties of Tb2Sn2O7
    L. T. Denisova
    L. A. Irtyugo
    Yu. F. Kargin
    V. V. Beletskii
    V. M. Denisov
    Inorganic Materials, 2017, 53 : 93 - 95
12345