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• 2. Estimating and correcting interference fringes in infrared spectra in infrared hyperspectral imaging
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• 3. Enabling stable MnO2 matrix for aqueous zinc-ion battery cathodes?
  Yiding Jiao,Liqun Kang,Jasper Berry-Gair,Kit McColl,Jianwei Li,Haobo Dong,Hao Jiang,Ryan Wang,Furio Corà,Dan J. L. Brett,Ivan P. Parkin J. Mater. Chem. A, 2020,8, 22075-22082
• 4. Fe3O4/PEG-SO3H as a heterogeneous and magnetically-recyclable nanocatalyst for the oxidation of sulfides to sulfones or sulfoxides
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• Catalysts and Inorganic Chemicals Inorganic Compounds Mixed metal/non-metal compounds Transition metal oxoanionic compounds Transition metal phosphates

Zinc Phosphate Tetrahydrate: A Comprehensive Overview

Zinc phosphate tetrahydrate, also known as zinc phosphate with the CAS number 7543-51-3, is a versatile inorganic compound that has garnered significant attention in various industrial and scientific applications. This compound, chemically represented as Zn₃(PO₄)₂·4H₂O, is widely recognized for its unique chemical properties and wide-ranging utility across multiple sectors. In recent years, advancements in material science and green chemistry have further highlighted its potential for innovative applications, making it a subject of intense research interest.

The molecular structure of zinc phosphate tetrahydrate consists of zinc ions (Zn2?) coordinated with phosphate groups (PO₄^3-) and water molecules in a hydrated form. This structure contributes to its stability and reactivity under various conditions. Recent studies have explored the influence of hydration on the compound's physical and chemical properties, revealing insights into its thermal stability and catalytic activity. For instance, research published in the Journal of Materials Chemistry has demonstrated that the tetrahydrate form exhibits superior catalytic performance in certain reactions compared to its anhydrous counterpart.

The synthesis of zinc phosphate tetrahydrate can be achieved through several methods, including precipitation from aqueous solutions, hydrothermal synthesis, and solid-state reactions. Each method offers distinct advantages depending on the desired product characteristics. A notable advancement in this area involves the use of green chemistry principles to minimize environmental impact during synthesis. For example, researchers have successfully employed microwave-assisted synthesis to produce zinc phosphate tetrahydrate with high purity and reduced energy consumption.

Zinc phosphate tetrahydrate finds extensive application in industries such as coatings, adhesives, catalysts, and even biomedicine. In the coatings industry, it serves as a corrosion-resistant additive due to its ability to form protective layers on metal surfaces. Recent studies have explored its integration with nanomaterials to enhance coating durability under harsh environmental conditions.

In the field of catalysis, zinc phosphate tetrahydrate has emerged as a promising material for heterogeneous catalysis in organic transformations. Its porous structure and high surface area make it an ideal candidate for facilitating various reactions, including esterification and oxidation processes. A study published in Applied Catalysis B: Environmental highlighted its effectiveness in reducing pollutants such as nitrogen oxides (NOx) under mild operating conditions.

The biomedical applications of zinc phosphate tetrahydrate are equally compelling. It has been investigated for use in drug delivery systems due to its biocompatibility and controlled drug release properties. Researchers have also explored its potential as a bioactive coating for implants, demonstrating enhanced osseointegration in preclinical studies.

Recent advancements in computational chemistry have further deepened our understanding of zinc phosphate tetrahydrate's electronic structure and reactivity at the molecular level. Density functional theory (DFT) calculations have provided insights into its catalytic mechanisms and electronic transitions, paving the way for tailored modifications to enhance performance.

In terms of environmental impact, zinc phosphate tetrahydrate is considered relatively safe when handled appropriately. However, proper disposal methods are essential to prevent contamination of water bodies or soil ecosystems.

The future outlook for zinc phosphate tetrahydrate appears promising as ongoing research continues to uncover new applications across diverse fields.

• 7779-90-0(Zinc phosphate)
• 7783-28-0(Diammonium phosphate)
• 13845-36-8(Pentapotassium triphosphate)
• 16788-57-1(Dipotassium hydrogen phosphate trihydrate)
• 13308-51-5(Boron phosphate)
• 7722-76-1(Ammonium dihydrogen phosphate)
• 7758-11-4(Phosphoric Acid Dipotassium)
• 7778-53-2(Potassium Phosphate Tribasic)
• 10101-89-0(Trisodium phosphate dodecahydrate)
• 7778-77-0(Potassium Phosphate Monobasic)