Trimorphic TaCrP – A diffraction and 31P solid state NMR spectroscopic study

IF 0.9 4区材料科学 Q3 CRYSTALLOGRAPHY

Zeitschrift Fur Kristallographie-Crystalline Materials Pub Date : 2023-02-06 DOI:10.1515/zkri-2022-0070

C. Paulsen, Josef Maximilian Gerdes, V. Svitlyk, M. Reimann, Alfred Rabenbauer, T. Nilges, M. Hansen, R. Pöttgen

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Abstract

Abstract The metal-rich phosphide TaCrP forms from the elements by step-wise solid state reaction in an alumina crucible (maximum annealing temperature 1180 K). TaCrP is trimorphic. The structural data of the hexagonal ZrNiAl high-temperature phase (space group P 6 ‾ 2 m $P\overline{6}2m$ ) was deduced from a Rietveld refinement. At room temperature TaCrP crystallizes with the TiNiSi type (Pnma, a = 623.86(5), b = 349.12(3), c = 736.78(6) pm, wR = 0.0419, 401 F2 values, 20 variables) and shows a Peierls type transition below ca. 280 K to the monoclinic low-temperature modification (P121/c1, a = 630.09(3), b = 740.3(4), c = 928.94(4) pm, β = 132.589(5)°, wR = 0.0580, 1378 F2 values, 57 variables). The latter phase transition is driven by pairwise Cr–Cr bond formation out of an equidistant chain in o-TaCrP. The phase transition was monitored via different analytical tools: differential scanning calorimetry, powder synchrotron X-ray diffraction, magnetic susceptibility measurements and 31P solid state NMR spectroscopy.

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三晶型TaCrP - A的衍射和31P固体核磁共振光谱研究

摘要在氧化铝坩埚（最高退火温度1180 K）中，元素通过分步固态反应形成富含金属的磷化物TaCrP。TaCrP是三形态的。六方ZrNiAl高温相（空间群P6‾2 m$P\overline）的结构数据{6}2m$）是从Rietveld精化中推导出来的。在室温下，TaCrP结晶为TiNiSi型（Pnma，a=623.86（5），b=349.12（3），c=736.78（6）pm，wR=0.0419，401 F2值，20个变量），并在约280 K以下显示Peierls型转变为单斜低温改性（P121/c1，a=630.09（3）、b=740.3（4），c=928.94（4）pm，β=132.589（5）°，wR=0.0580，1378 F2值，57个变量）。后一种相变是由o-TaCrP中等距链形成的成对Cr–Cr键驱动的。通过不同的分析工具监测相变：差示扫描量热法、粉末同步加速器X射线衍射、磁化率测量和31P固态NMR光谱。

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来源期刊

Zeitschrift Fur Kristallographie-Crystalline Materials CRYSTALLOGRAPHY-

CiteScore

2.00

自引率

16.70%

发文量

期刊介绍： Zeitschrift für Kristallographie – Crystalline Materials was founded in 1877 by Paul von Groth and is today one of the world’s oldest scientific journals. It offers a place for researchers to present results of their theoretical experimental crystallographic studies. The journal presents significant results on structures and on properties of organic/inorganic substances with crystalline character, periodically ordered, modulated or quasicrystalline on static and dynamic phenomena applying the various methods of diffraction, spectroscopy and microscopy.