Oxoborates of the ludwigite group: Natural and mineral-like compounds as prospective materials

LITHOSPHERE (Russia) Pub Date : 2024-05-03 DOI:10.24930/1681-9004-2024-24-2-226-239

Y. Biryukov, A. L. Zinnatullin, R. S. Bubnova, F. Vagizov, A. Shablinskii, S. K. Filatov, I. Pekov

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Abstract

Research subject. Natural oxoborates of the ludwigite group, including azoproite, ludwigite, and vonsenite. Their empirical formulas based on five oxygen atoms have the following form: azoproite (Mg1.81Fe2+0.19)∑2.00(Fe3+0.36Ti0.26Mg0.26Al0.12)∑1.00 O2(BO3), ludwigite (Mg1.69Fe2+0.30Mn2+0.01)Σ2.00(Fe3+0.90Al0.07Mg0.02Sn0.01)Σ1.00O2(BO3) and vonsenite (Fe2+1.86Mg0.13)∑1.99 (Fe3+0.92Mn2+0.05Sn4+0.02Al0.02)∑1.01O2(BO3). Aim. To establish the relationship between the composition, crystal structure, and thermal behavior (293–1373 K) of the minerals. Materials and methods. Ludwigite was collected at the Iten’yurginskoe tin skarn deposit; vonsenite was collected at the Titovskoe magnesium-skarn boron deposit; azoproite was collected at magnesian skarns of the Tazheran alkaline massif. The methods of single crystal X-ray diffraction, energy dispersive X-ray spectroscopy, high-temperature X-ray diffraction, Mössbauer spectroscopy, and thermal analysis were used. Results. Low-charge cations (Fe2+, Fe2.5+, Mg2+) tend to occupy the M(1)–M(3) sites, and high-charge cations (Fe3+, Al3+, Ti4+, Sn4+) generally occupy the M(4) site. Azoproite is characterized by the highest melting temperature Tm > 1650 K. Due to the low Fe2+ content, azoproite does not undergo solid-phase decomposition across the investigated temperature range. The melting point of ludwigite exceeds 1582 K, which is due to the high Mg content; as a result of the Fe2+ → Fe3+ oxidation, it gradually decomposes with the formation of hematite, warwickite, and magnetite. The temperatures of oxidation and solid-phase decomposition in the Fe2+-rich vonsenite are approximately 100 K lower than those in ludwigite. The melting point of vonsenite is 1571 K. All the minerals are characterized by a weak degree of thermal expansion anisotropy. The main contribution to the thermal expansion anisotropy is due to the preferred orientation of the [BO3]3– triangles. Conclusions. The thermal properties of the oxoborates depend on their chemical composition. It was established that Tm increases with an increase in the Mg and Ti4+ content, and decreases with an increase in the Fe2+ content. The Fe2+ → Fe3+ oxidation is observed when the FeO component in the minerals exceeds 10 wt %, which leads to the solid-phase decomposition starting at temperatures of about 500–600 K. The values of the 293KαV volume thermal expansion of ludwigite and azoproite are comparable, while the largest values were observed for vonsenite. This is associated with the largest average bond lengths, primarily those of 6.

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褐铁矿类氧化硼酸盐：作为未来材料的天然化合物和类矿物化合物

研究课题。卢德韦希石族的天然氧硼酸盐，包括偶氮沸石、卢德韦希石和冯森石。它们基于五个氧原子的经验公式有如下形式：偶氮沸石（Mg1.81Fe2+0.19）∑2.00(Fe3+0.36Ti0.26Mg0.26Al0.12)∑1.00 O2(BO3)，绿泥石（Mg1.69Fe2+0.30Mn2+0.01)Σ2.00(Fe3+0.90Al0.07Mg0.02Sn0.01)Σ1.00O2(BO3) and vonsenite (Fe2+1.86Mg0.13)∑1.99 (Fe3+0.92Mn2+0.05Sn4+0.02Al0.02)∑1.01O2(BO3).目的是确定矿物的组成、晶体结构和热行为（293-1373 K）之间的关系。材料和方法。在 Iten'yurginskoe 锡矽卡岩矿床中采集了路德维希石；在 Titovskoe 镁矽卡岩硼矿床中采集了钒硒矿；在塔泽兰碱性丘陵的镁矽卡岩中采集了天青石。采用了单晶 X 射线衍射、能量色散 X 射线光谱、高温 X 射线衍射、莫斯鲍尔光谱和热分析等方法。研究结果低电荷阳离子（Fe2+、Fe2.5+、Mg2+）往往占据 M(1)-M(3) 位，而高电荷阳离子（Fe3+、Al3+、Ti4+、Sn4+）一般占据 M(4) 位。由于 Fe2+ 含量较低，在所研究的温度范围内，偶氮普罗石不会发生固相分解。褐铁矿的熔点超过 1582 K，这是由于镁含量较高；由于 Fe2+ → Fe3+ 氧化作用，褐铁矿逐渐分解，形成赤铁矿、褐铁矿和磁铁矿。富含 Fe2+ 的冯硒铁的氧化温度和固相分解温度比卢氏铁低约 100 K。所有矿物都具有较弱的热膨胀各向异性。热膨胀各向异性的主要原因是[BO3]3- 三角形的优先取向。结论。氧化硼酸盐的热性质取决于其化学成分。研究发现，Tm 随 Mg 和 Ti4+ 含量的增加而增加，随 Fe2+ 含量的增加而减少。当矿物中的 FeO 成分超过 10 wt % 时，就会出现 Fe2+ → Fe3+ 氧化，导致固相分解在约 500-600 K 的温度下开始。这与最大的平均键长有关，主要是 6.

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LITHOSPHERE (Russia)

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