磷灰石 OH-Cl 二元系统红外光谱中的 OH 伸缩区域

IF 2.7 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
R. Tacker, John Rakovan, Daniel Harlov, John M. Hughes, Sarah B. Cichy
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引用次数: 0

摘要

对羟基磷灰石-氯磷灰石固溶体的羟基伸展区进行偏振傅立叶变换红外(FTIR)微光谱分析,为将峰值分配到特定的羟基-氯对提出了新的问题。Hughes 等人(2016 年)的晶体结构细化确定了合成混合 Cl-OH 磷灰石中柱阴离子的新位置,根据成分的不同,柱阴离子有三种不同的排列方式。这些结构细化与键价计算相结合,可以解释羟基伸展区域。3574 cm-1 处的峰值被确定为来自羟基磷灰石末端成员的峰值。3548 cm-1 处的第二个主要峰值只出现在绿磷灰石-羟基磷灰石混合固溶体中,第三个峰值出现在 3592 cm-1 处。与羟基磷灰石相比,这两个峰都代表了羟基拉伸振动的扰动,分别频率较低和较高。这两个新峰值都是 Clb-OH 序列的结果,相邻的阴离子处于晶体学上相似的位置,都在相邻镜面的上方或下方。一种构型的氢原子指向氯原子。第二种构型是羟基的氢原子远离氯原子。这两种构型都带来了新的问题。3548 cm-1 处向较低波长的移动是氟磷灰石-羟基磷灰石混合物中氢键的特征,但 O(H)和 Clb 之间的距离太大,无法实现这种移动。羟基伸缩振动向低波数移动是由于中间的 Cl-Ca2'(或 Ca2)键和 Ca2(')-O3 键的极化发生了变化,而这些变化会受到大的氯原子存在的影响。降低 OH 伸缩振动模拟了磷灰石 c 轴柱中一个氯原子对邻近 OH 基团的预期影响,尽管没有氢键。向更高文数的移动,即 3592 cm-1 处频率的升高,与磷灰石矿物组中柱阴离子之间氢键作用的预期相反。这是由于相邻的 Clb 与相邻 OH 偶极的氧端之间的相互作用造成的。这种配对将一个氧原子和一个氯原子紧密地结合在一起。讨论了可能的适应方式。3498 cm-1 处无处不在的峰值代表 OH 与 OHa 位点之间的氢键作用,氧间距离约为 2.9 Å。然而,在缺乏 OHa 的标本的晶体结构细化中,虽然存在红外线吸收,但没有观察到与这种配对明显对应的现象。对等离子喷射生物材料的研究推断出了氧磷灰石的存在,但替代物的晶体学细节仍然难以捉摸。3517 cm-1 处的一个小肩在结构细化中没有明确的对应物。可以排除三个柱状阴离子(如 OH-Cl-OH 或 Cl-OH-OH)的序列,但明确的分配有待进一步研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The OH stretching region in infrared spectra of the apatite OH-Cl binary system
Polarized Fourier Transform Infrared (FTIR) microspectroscopy of the OH stretching region of hydroxylapatite-chlorapatite solid solutions presents novel problems for the assignment of peaks to specific OH-Cl pairs. Crystal structure refinements of Hughes et al. (2016) identified new positions for column anions in synthetic mixed Cl-OH apatites, with three different column anion arrangements depending on composition. These structural refinements, combined with bond valence calculations, allow for interpretation of the OH stretching region. A peak at 3574 cm-1 is identified as that from end member hydroxylapatite. A second major peak at 3548 cm-1 is only found in mixed chlorapatite-hydroxylapatite solid solutions, as is a third peak at 3592 cm-1. Both represent perturbations of the OH stretching vibration as compared to hydroxylapatite, to lower and higher frequency, respectively. Both of the new peaks are the result of a Clb-OH sequence, with adjacent anions in crystallographically similar positions, both above or both below adjacent mirror planes. One configuration has the hydrogen atom pointed towards the chlorine atom. The second has the hydrogen of the OH group pointed away from the chlorine atom. Both configurations present novel problems. The shift to lower wavenumber at 3548 cm-1 is characteristic of hydrogen bonding in fluorapatite-hydroxylapatite mixtures, yet the distance between O(H) and Clb is too great to allow it. The shift of OH stretching vibrations to lower wavenumber is produced through changes in polarization of intervening Cl-Ca2’ (or Ca2) and Ca2(’)-O3 bonds, which are affected by the presence of the large chlorine atom. Lowering the OH stretching vibration mimics the expected effect of a chlorine on a neighboring OH group in the apatite c-axis column, though without hydrogen bonding. The shift to higher wavenumbers, i.e. higher frequency at 3592 cm-1, is the opposite of that expected for hydrogen bonding between column anions in the apatite mineral group. It is ascribed to interaction between an adjacent Clb and the oxygen end of an adjacent OH dipole. This pairing places an oxygen and a chlorine atom in close proximity. Possible means of accommodation are discussed. A ubiquitous peak at 3498 cm-1 represents hydrogen bonding between an OH and the OHa site, with an interoxygen distance of about 2.9 Å. Published modeling supports the hypothesis that the OHa site is occupied by an O rather than an OH. However, no clear counterpart to this pairing is observed in crystal structure refinements for specimens lacking OHa, although the infrared absorbance is present. The existence of oxyapatite is inferred from studies of plasma-sprayed biomaterials, but the crystallographic details of the substitution have remained elusive. A minor shoulder at 3517 cm-1 does not have a clear counterpart in the structural refinements. Sequences of three columnar anions (e.g. OH-Cl-OH or Cl-OH-OH) can be ruled out, but unequivocal assignment awaits further research.
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来源期刊
American Mineralogist
American Mineralogist 地学-地球化学与地球物理
CiteScore
5.20
自引率
9.70%
发文量
276
审稿时长
1 months
期刊介绍: American Mineralogist: Journal of Earth and Planetary Materials (Am Min), is the flagship journal of the Mineralogical Society of America (MSA), continuously published since 1916. Am Min is home to some of the most important advances in the Earth Sciences. Our mission is a continuance of this heritage: to provide readers with reports on original scientific research, both fundamental and applied, with far reaching implications and far ranging appeal. Topics of interest cover all aspects of planetary evolution, and biological and atmospheric processes mediated by solid-state phenomena. These include, but are not limited to, mineralogy and crystallography, high- and low-temperature geochemistry, petrology, geofluids, bio-geochemistry, bio-mineralogy, synthetic materials of relevance to the Earth and planetary sciences, and breakthroughs in analytical methods of any of the aforementioned.
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