Condensed Phosphates and Arsenates

Thilo, Erich

doi:10.1016/s0065-2792(08)60265-4

Cited by 85 publications

(28 citation statements)

References 270 publications

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“…We attribute this to the polymorphic behavior of CsPO 3 , which is known to crystallize in long-chain, cyclic and other forms depending on the details of the thermal history and preparation methods. 15 On the basis of the work of Osterheld and Markowitz, 10 who used the Jones method 16 to analyze the dehydration products of CsH 2 PO 4 obtained under similar dry conditions, we conclude that the product phase generated in this study is long-chain CsPO 3 .…”

Section: X-ray Powder Diffraction Analysis Of Reaction Productsmentioning

confidence: 61%

“…15 It is reasonable to assume that the dehydration of CsH 2 PO 4 occurs similarly, with slow diffusion of gasphase H 2 O through the product layer limiting the rate of transformation of the un-reacted shrinking core. It can be shown for such a process that the lag, DT, in the dehydration temperature from its equilibrium value is proportional to the square root of the heating rate.…”

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confidence: 99%

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Dehydration behavior of the superprotonic conductor CsH2PO4 at moderate temperatures: 230 to 260 °C

et al. 2007

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The dehydration behavior of caesium dihydrogen phosphate CsH 2 PO 4 was investigated in the temperature range of 230 uC to 260 uC under high humidity, conditions of particular relevance to the operation of fuel cells based on this electrolyte. The onset temperature of dehydration was determined from changes in ionic conductivity on heating and confirmed by weight change measurements under isothermal conditions. The relationship between the onset temperature of dehydration (T dehy ) and water partial pressure (p H 2 O ) was determined to be log(p H 2 O /atm = 6.11(¡0.82) 2 3.63(¡0.42) 6 1000/(T dehy /K), from which the thermodynamic parameters of the dehydration reaction from CsH 2 PO 4 to CsPO 3 were evaluated. The dehydration pathway was then probed by X-ray powder diffraction analysis of the product phases and by thermogravimetric analysis under slow heating. It was found that, although the equilibrium dehydration product is solid caesium metaphosphate CsPO 3 , the reaction occurs via two overlapping steps: CsH 2 PO 4 A Cs 2 H 2 P 2 O 7 A CsPO 3 , with solid caesium hydrogen pyrophosphate, Cs 2 H 2 P 2 O 7 , appearing as a kinetically favored, transient phase.

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Section: X-ray Powder Diffraction Analysis Of Reaction Productsmentioning

confidence: 61%

mentioning

confidence: 99%

Dehydration behavior of the superprotonic conductor CsH2PO4 at moderate temperatures: 230 to 260 °C

et al. 2007

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“…There are, however, large discrepancies in the literature concerning the nature of this transition, as well as regarding the number of additional transitions at higher temperatures. For example, a structural phase transition from tetragonal to monoclinic symmetry has been proposed for KDP at 180 °C [7,8]. Other researchers have proposed that when the KDP-type compounds are heated above room temperature, loss of water will take place, as in the following chemical reaction [10];…”

Section: Introductionmentioning

confidence: 99%

Growth and thermal studies on pure ADP, KDP and mixed K_1‐x(NH₄)_xH₂PO₄ crystals

Shenoy¹,

Bangera

Shivakumar

2010

Cryst. Res. Technol.

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The investigations on the formation of mixed crystals of ammonium dihydrogen orthophosphate (ADP) and potassium dihydrogen orthophosphate (KDP) i.e. potassium ammonium dihydrogen phosphate, K 1-x (NH 4 ) x H 2 PO 4 have been presented in this paper. Pure and mixed crystals of ADP and KDP have been grown by slow evaporation technique from the supersaturated solution at an ambient temperature 26±1 °C for ammonium concentration x in the range 0.0 ≤ x ≤ 1.0 in the case of mixed crystals. Crystal compositions were determined by flame atomic absorption spectroscopy and chemical analysis. The results of the X-ray analysis of the grown crystals are also reported. Thermogravimetric analysis (TGA) and differential thermal analysis (DTA) were used to study the kinetic process of dehydration and the high temperature phase behaviour. DTA showed the distinct thermal events attributed to dehydration of ADP, KDP and K 1-x (NH 4 ) x H 2 PO 4 . The results of thermal analysis and chemical analysis are consistent with each other.

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“…This result is not surprising since the ultimate products of the thermal condensation of dihydrogenphosphates are the metaphosphates, particularly trimetaphosphate [2]; furthermore, the properties of linear polyphosphates 1 become closer to those of trimetaphosphate 2 when n is large, i.e. when the ratio (n-l)/n is close to 1 [2].…”

Section: Discussionmentioning

confidence: 99%

“…Besides sodium cyanide and cyanamide we have chosen imidazole for the following reasons: a) imidazole and imidazole derivatives are produced in simulated prebiotic reactions [ 121, b) imidazole plays a catalytic role in acyl [ 131 and phosphory12) [ 141 transfer reactions (l-phosphonatoimidazole 6 and 1 -triphosphonato-imidazole 7 transfer very easily the phosphoryl group to other sites and are often formed in model biochemical reactions as 'energy rich' intermediates [ 15]), and c) 1-(a-aminoacy1)imidazoles 8 give rise to peptides in aqueous solutions, the best yields of tripeptide (and higher peptides) being achieved precisely in the pH range 6-9 [16] which is of interest to us. Magnesium ion was also added in one experiment because of its catalysis of pyrophosphate breakdown in aqueous solutions [2], its catalysis of the synthesis of amino acid adenylate anhydride [17] and its use (together with imidazole) in simultaneous peptide and oligonucleotide formation in mixtures of amino acids and nucleoside-triphosphates [ 181. We hoped therefore to obtain more significant amounts of tripeptide by adding imidazole (or imidazole and MgC12) to our aqueous system of polyphosphate and amino acid, and by working at pH 9 or below.…”

Section: )mentioning

confidence: 99%

Influence of Imidazole and Hydrocyanic Acid Derivatives on the ‘Possible Prebiotic’ polyphosphate induced peptide synthesis in aqueous solution

Rabinowitz

Hampai

1978

Helvetica Chimica Acta

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Glycine in aqueous solutions of trimetaphosphate or linear polyphosphate at pH adjusted to 8.1‐9.0, is condensed at room temperature to diglycine and very small amounts of triglycine. The addition of imidazole increases the yield of triglycine by a factor of almost 10; supplementary addition of magnesium ion does not increase this effect. On the contrary to what has been observed at pH 11.5‐12.0, the addition of sodium cyanide or cyanamide at pH 8.1‐9.0 diminishes strongly the yield of triglycine and to a lesser degree that of diglycine. The prebiotic significance of the condensation of amino acids in aqueous solutions of polyphosphates in the presence of imidazole is discussed.

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Condensed Phosphates and Arsenates

Cited by 85 publications

References 270 publications

Dehydration behavior of the superprotonic conductor CsH2PO4 at moderate temperatures: 230 to 260 °C

Dehydration behavior of the superprotonic conductor CsH2PO4 at moderate temperatures: 230 to 260 °C

Growth and thermal studies on pure ADP, KDP and mixed K_1‐x(NH₄)_xH₂PO₄ crystals

Influence of Imidazole and Hydrocyanic Acid Derivatives on the ‘Possible Prebiotic’ polyphosphate induced peptide synthesis in aqueous solution

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Condensed Phosphates and Arsenates

Cited by 85 publications

References 270 publications

Dehydration behavior of the superprotonic conductor CsH2PO4 at moderate temperatures: 230 to 260 °C

Dehydration behavior of the superprotonic conductor CsH2PO4 at moderate temperatures: 230 to 260 °C

Growth and thermal studies on pure ADP, KDP and mixed K1‐x(NH4)xH2PO4 crystals

Influence of Imidazole and Hydrocyanic Acid Derivatives on the ‘Possible Prebiotic’ polyphosphate induced peptide synthesis in aqueous solution

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Growth and thermal studies on pure ADP, KDP and mixed K_1‐x(NH₄)_xH₂PO₄ crystals