Characterization of Orthophosphate and Orthovanadate in Aqueous Solution Using Polarized Raman Spectroscopy.

IF 2.2 3区化学 Q2 INSTRUMENTS & INSTRUMENTATION

Applied Spectroscopy Pub Date : 2024-09-05 DOI:10.1177/00037028241275107

Wolfram Rudolph

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Abstract

Polarized Raman spectroscopy was used to analyze aqueous solutions of sodium orthophosphate and orthovanadate over a wide concentration range (0.00891-0.702 mol/L) at 23 °C. The isotropic scattering profiles were obtained by measuring polarized Raman scattering spectra. Furthermore, R-normalized spectra were calculated and presented. The tetrahedral ions, VO₄^3-(aq) and PO₄^3-(aq), demand four Raman active bands which have been subsequently characterized and assigned. For the PO₄^3-(aq) ion, the deformation modes ν₂(e) and ν₄(f₂) appear at 415 and 557 cm^-1, and these modes are depolarized. In the P-O stretching region, the strongest Raman band appears at 936.5 cm^-1, which is totally polarized with a depolarization ratio (ρ-value) of 0.002. The broad and depolarized mode at 1010 cm^-1 constitutes the antisymmetric stretching band ν₃(f₂). The Raman spectrum of VO₄^3- shows two depolarized deformation modes ν₂(e) and ν₄(f₂) at 327 and 345.6 cm^-1, which are severely overlapped. These bands are very weak. The strongest band in the Raman spectrum of VO₄^3-(aq) is the symmetric stretching mode ν₁(a₁) at 820.2 cm^-1 which is totally polarized with a ρ-value at 0.004. The depolarized antisymmetric stretching mode ν₃(f₂) appeared at 785 cm^-1 as a broad and weak band. Both anions are strongly hydrated and showed extensive hydrolysis in an aqueous solution. Orthovanadate is a much stronger base than orthophosphate in aqueous solution. Therefore, a large amount of NaOH was used to suppress the hydrolysis of VO₄^3-(aq) sufficiently, so, it was possible to characterize the VO₄^3- modes. Quantitative Raman spectroscopy was applied to follow the hydrolysis of PO₄^3- over a wide concentration range from 0.00891 to 0.592 mol/L. The hydrolysis data allowed the calculation of the pK_a3 value for H₃PO₄ to be 12.330 ± 0.02 (25 °C). The hydrolysis of the VO₄^3- ion is ∼21 times larger than that of the PO₄^3-. The pK_a3 value for H₃VO₄ is estimated to be 13.65 ± 0.1 (25 °C).

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利用偏振拉曼光谱表征水溶液中的正磷酸盐和正钒酸盐

利用偏振拉曼光谱分析了 23 °C、宽浓度范围（0.00891-0.702 mol/L）的正磷酸钠和正钒酸盐水溶液。各向同性散射曲线是通过测量偏振拉曼散射光谱获得的。此外，还计算并展示了 R 归一化光谱。四面体离子 VO43-(aq) 和 PO43-(aq) 需要四个拉曼活性带，随后对其进行了表征和分配。对于 PO43-（aq）离子，变形模式 ν2(e)和 ν4(f2)出现在 415 和 557 cm-1 处，这些模式是去极化的。在 P-O 伸展区域，最强的拉曼光谱带出现在 936.5 cm-1 处，它是完全偏振的，去极化率（ρ 值）为 0.002。1010 cm-1 处的宽去极化模式构成了反对称拉伸带 ν3(f2)。VO43- 的拉曼光谱在 327 和 345.6 cm-1 处显示出两个去极化形变模式 ν2(e) 和 ν4(f2) ，这两个模式严重重叠。这些波段非常微弱。VO43-(aq) 拉曼光谱中最强的波段是 820.2 cm-1 处的对称伸展模式 ν1(a1)，它完全极化，ρ 值为 0.004。去极化的不对称伸展模式 ν3(f2)出现在 785 cm-1 处，是一个宽而弱的频带。这两种阴离子都具有很强的水合作用，在水溶液中会发生广泛的水解。在水溶液中，正钒酸盐是一种比正磷酸盐更强的碱。因此，需要使用大量的 NaOH 来充分抑制 VO43-(aq) 的水解，这样才能确定 VO43- 模式的特征。定量拉曼光谱被用于跟踪 PO43- 在 0.00891 至 0.592 mol/L 的宽浓度范围内的水解过程。通过水解数据可以计算出 H3PO4 的 pKa3 值为 12.330 ± 0.02（25 °C）。VO43- 离子的水解作用比 PO43- 大 21 倍。H3VO4 的 pKa3 值估计为 13.65 ± 0.1（25 °C）。

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来源期刊

Applied Spectroscopy 工程技术-光谱学

CiteScore

6.60

自引率

5.70%

发文量

139

审稿时长

3.5 months

期刊介绍： Applied Spectroscopy is one of the world''s leading spectroscopy journals, publishing high-quality peer-reviewed articles, both fundamental and applied, covering all aspects of spectroscopy. Established in 1951, the journal is owned by the Society for Applied Spectroscopy and is published monthly. The journal is dedicated to fulfilling the mission of the Society to “…advance and disseminate knowledge and information concerning the art and science of spectroscopy and other allied sciences.”