zinc phenylphosphonate monohydrate | 122780-95-4
中文名称
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中文别名
——
英文名称
zinc phenylphosphonate monohydrate
英文别名
zinc phenylphosphate monohydrate;zinc;dioxido-oxo-phenyl-λ5-phosphane;hydrate
CAS
122780-95-4;45986-33-2
化学式
C6H5O3P*H2O*Zn
mdl
——
分子量
239.483
InChiKey
QCCZHLZTSRCUMX-UHFFFAOYSA-L
BEILSTEIN
——
EINECS
——
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物化性质
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计算性质
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ADMET
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安全信息
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SDS
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制备方法与用途
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上下游信息
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文献信息
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表征谱图
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同类化合物
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相关功能分类
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相关结构分类
计算性质
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辛醇/水分配系数(LogP):-1.6
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重原子数:12
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可旋转键数:0
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环数:1.0
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sp3杂化的碳原子比例:0.0
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拓扑面积:64.2
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氢给体数:1
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氢受体数:4
反应信息
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作为反应物:描述:zinc phenylphosphonate monohydrate 以 neat (no solvent) 为溶剂, 生成 zinc phenylphosphonate参考文献:名称:Frink, Karen J.; Wang, Ren-Chain; Colón, Jorge L., Inorganic Chemistry, 1991, vol. 30, # 7, p. 1438 - 1441摘要:DOI:
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作为产物:描述:zinc phenylphosphonate 在 H2O 作用下, 以 neat (no solvent) 为溶剂, 生成 zinc phenylphosphonate monohydrate参考文献:名称:Frink, Karen J.; Wang, Ren-Chain; Colón, Jorge L., Inorganic Chemistry, 1991, vol. 30, # 7, p. 1438 - 1441摘要:DOI:
文献信息
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Thermal Behavior of Zinc Phenylphosphonate and Structure Determination ofγ-Zn2P2O7from X-Ray Powder Diffraction Data作者:T. Bataille、P. Bénard-Rocherullé、D. LouërDOI:10.1006/jssc.1998.7854日期:1998.10The thermal behavior of zinc phenylphosphonate has been studied by temperature-dependent X-ray powder diffraction and thermo-gravimetry in the temperature range 19–600°C. The different phases occurring during the decomposition have been identified, i.e., the anhydrous phase and the three successive polymorphic varieties of Zn2P2O7. The first one is amorphous,δ-Zn2P2O7is poorly crystalline, andγ-Zn2P2O7is通过在19–600°C的温度范围内通过温度依赖性X射线粉末衍射和热重分析法研究了苯基膦酸锌的热行为。已经确定了在分解过程中发生的不同相,即无水相和Zn 2 P 2 O 7的三个连续的多态变体。第一个是非晶态的,δ- Zn 2 P 2 O 7的结晶性较差,而γ- Zn 2 P 2 O 7的则是亚稳相。最后一个在较高温度下转变为β变体。γ的晶体结构-Zn 2 P 2 O 7从头开始是用常规单色X射线收集的粉末衍射数据解决的。对称性是正交的,单元尺寸为a = 4.9504(5)Å,b = 13.335(2)Å,c = 16.482(3)Å,空间群Pbcm,Z = 8。该结构由沿着[001]延伸的ZnO 5三角双锥体的无限波纹链组成。这些链通过另外两个方向的P 2 O 7基团连接在一起。P 2 O 4− 7与α和β相相反,阴离子显示出低角度和黯淡的构象。
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An organometallic sol–gel route to layered zinc phenylphosphonate and encapsulation studies with η6-(C6H6)Cr(CO)3作者:Robert W Deemie、Muralidhar Rao、D.Andrew KnightDOI:10.1016/s0022-328x(99)00209-0日期:1999.8white gel. The gel was dried in air at room temperature for 8 h to give the layered compound [ZnC6H5PO3]·H2O (1). This process represents a convenient non-aqueous organometallic sol–gel route to a layered metal phosphonate material. Zinc phenylphosphonate synthesized using the sol–gel method is identical to that prepared using the conventional aqueous precipitation technique as determined by IR spectroscopy
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Tailoring the photoluminescence properties of transition metal phosphonates作者:Richard Singleton、James Bye、James Dyson、Gary Baker、Robert M. Ranson、Gary B. HixDOI:10.1039/c000531b日期:——A series of phenylphosphonates, Zn1−xMnx(O3PC6H5)·H2O, where x = 0, 0.005, 0.25, 0.5, 0.75 and 1.0, has been prepared and their photoluminescence responses studied. The presence of Mn in the sample results in a red emission, whilst when x = 0 the emission is green. Levels of Mn <1 mol% result in an orange emission. Ag6(m-O3PC6H4CO2)2 has been prepared by hydrothermal reaction of Ag(NO3) and m-phosphonobenzoic acid. The material has a 1D channel structure in which the channels are lined with the phenyl groups. Ag6(m-O3PC6H4CO2)2 shows a green luminescence response to laser excitation, whilst the related Zn material, Zn3(m-O3PC6H4CO2)2, shows an unusual yellow emission.
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Divalent metal phenylphosphonates and phenylarsonates作者:Desmond Cunningham、Patrick J.D. Hennelly、Tony DeeneyDOI:10.1016/s0020-1693(00)95524-5日期:1979.1
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Selected-Control Synthesis of Metal Phosphonate Nanoparticles and Nanorods作者:Shu-Yan Song、Jian-Fang Ma、Jin Yang、Min-Hua Cao、Ke-Chun LiDOI:10.1021/ic048436t日期:2005.4.1By surfactant-assisted methods, nanoscale Co(O3PC6H5)center dot H2O species of different morphologies, namely, nanoparticles and nanorods, have been successfully synthesized and characterized. Upon removal of the organic part of the compound, peculiar Co2P2O7 porous nanorods formed.
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