Studies of structure and phase transition in [C(NH2)(3)]HgBr3 and [C(NH2)(3)]HgI3 by means of halogen NQR, H-1 NMR, and single crystal X-ray diffraction
H. Terao et al., Studies of structure and phase transition in [C(NH2)(3)]HgBr3 and [C(NH2)(3)]HgI3 by means of halogen NQR, H-1 NMR, and single crystal X-ray diffraction, Z NATURFO A, 55(1-2), 2000, pp. 230-236
Citations number
8
Categorie Soggetti
Physical Chemistry/Chemical Physics
Journal title
ZEITSCHRIFT FUR NATURFORSCHUNG SECTION A-A JOURNAL OF PHYSICAL SCIENCES
The crystal structure of [C(NH2)(3)]HgBr3 was determined at room temperatur
e: monoclinic, space group C2/c, Z = 4, a = 775.0(2), b = 1564.6(2), c = 77
2.7(2) pm, beta = 109.12(2)degrees In the crystal, almost planar HgBr3- ion
s are connected via Hg ... Br bonds, resulting in single chains of trigonal
bipyramidal HgBr5 units which run along the c direction. [C(NH2)(3)]HgI3 w
as found to be isomorphous with the bromide at room temperature. The temper
ature dependence of the halogen NQR frequencies (77 < T/K < ca. 380) and th
e DTA measurements evidenced no phase transition for the bromide, but a sec
ond-order phase transition at (251 +/- 1) K (T-c1) and a first-order one at
(210 +/- 1) K (T-c2) for the iodide. The transitions at T-c2 are accompani
ed with strong supercooling and significant superheating. The room temperat
ure phase (RTP) and the intermediate temperature phase (ITP) of the iodide
are characterized by two (127)(m=1/2<->3/2) NQR lines which are assigned to
the terminal and the bridging I atoms, respectively. There exist three lin
es in the lowest temperature phase (LTP), indicating that the resonance lin
e of the bridging atom splits into two. The signal intensities of the I-127
((m=1/2<->3/2)) NQR lines in the LTP decrease with decreasing temperature r
esulting in no detection below ca. 100 K. The I-127((m=1/2<->3/2)) NQR freq
uency vs. temperature curves are continuous at T-c1, but they are unusual i
n the LTP. The T-1 vs. T curves of H-1 NMR for the bromide and iodide are e
xplainable by the reorientational motions of the cations about their pseudo
three-fold axes. The estimated activation energies of the motions are 35.0
kJ/mol for the bromide, and 24.1, 30.1, and 23.0 kJ/mol for the RTP, ITP,
and LTP of the iodide, respectively.