Physiochemical Characterization of Iodine (V) Oxide: Hydration Rates

Physiochemical Characterization of Iodine (V) Oxide: Hydration Rates

In the first of a series of papers on the iodine (V) oxide system, the chemical and physical properties associated with iodine (V) oxide in its anhydride (I2O5) and hydrated states (HI3O8 and HIO3) are examined. The three forms of the oxide have been investigated utilizing differential scanning calo...

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Bibliographische Detailangaben
Hauptverfasser: Little, Brian K, Emery, Samuel B, Nittinger, Joshua C, Fantasia, Ryan C, Lindsay, C M
Format: Report
Sprache:eng
Schlagworte:
ACIDS
ANHYDRIDES
DIFFERENTIAL SCANNING CALORIMETRY
DIFFUSION
DSC(DIFFERENTIAL SCANNING CALORIMETRY)
ENERGETIC MATERIALS
ENERGETIC PROPERTIES
HI3O8(TRIPERIODIC ACID)
HIO3(IODIC ACID)
HIO3-I2O5
HYDRATION
HYDRATION RATES
HYDROGEN IODATES
I2O5(IODINE PENTOXIDES)
Inorganic Chemistry
IODATES
IODINE
IODINE OXIDES
NUCLEATION
OXIDES
OXIDIZERS
PE62602F
Physical Chemistry
PHYSIOCHEMICAL CHARACTERIZATION
PXRD(POWDER X-RAY DIFFRACTION)
SURFACE AREA
TGA(THERMOGRAVIMETRIC ANALYSIS)
THERMOGRAVIMETRIC ANALYSIS
W0DC
X RAY DIFFRACTION
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Zusammenfassung:In the first of a series of papers on the iodine (V) oxide system, the chemical and physical properties associated with iodine (V) oxide in its anhydride (I2O5) and hydrated states (HI3O8 and HIO3) are examined. The three forms of the oxide have been investigated utilizing differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), and powder X-ray diffraction (PXRD). In addition, the hydration rates governing the conversion of the anhydride (I2O5) to the initial hydrate (HI3O8) and later to the final hydrated state (HIO3) are reported and discussed. Results from this study suggest that the hydration mechanism for I2O5 to HI3O8 begins with an accelerating period described as a nucleation and growth phase followed by a decelerating period that is diffusion limited. The initial rate of hydration was observed to be governed by the nucleation and growth mechanism, which was inhibited by covering the surface of the particle with an inert metal. Based on this investigation the initial rate of hydration appears to be strongly dependent on the anhydride's available surface area which facilitates nucleation and growth of HI3O8. The original document contains color images.