Investigation on the regeneration of Z‐cut KDP crystals

Zhong, Degao; Teng, Bing; Yu, Zhenghe; Wang, Shuhua; Jiang, Xuejun; He, Ling; Huang, Wanxia

doi:10.1002/crat.201100159

Cryst. Res. Technol.

2011

DOI: 10.1002/crat.201100159

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Investigation on the regeneration of Z‐cut KDP crystals

Degao Zhong

Bing Teng

Zhenghe Yu

et al.

Abstract: The regeneration of Z-cut KDP crystals is explored by analyzing the growth of thin surface layers formed. The structural defects and crystalline perfection of the thin surface layers are evaluated by white-beam synchrotron radiation topography and high-resolution X-Ray diffraction respectively. It shows that the thin surface layers have the same crystal structure as KDP crystal. There are large numbers of defects in thin surface layers and the crystalline quality is very poor. The growth velocity of thin surfa… Show more

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Cited by 4 publications

References 13 publications

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Experimental Research on the Regeneration of Incomplete Crystallographic KH₂PO₄ Crystal Enclosed by Singular Face

Wang

Xiao

2019

Crystal Research and Technology

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The phenomenon of thin surface layer growth during the regeneration of incomplete crystallographic potassium dihydrogen phosphate crystal has not been thoroughly elucidated to date. In the present study, four sets of incomplete crystallographic KH 2 PO 4 crystals enclosed by singular faces are designed to observe their regeneration characteristics in supersaturated solution. In all the crystals, even though every crystal face is singular surface, thin surface layers still grow from crystal edges or concave angles to repair themselves to convex polyhedrons. Through surface energy calculation, it is found that the thin surface layer growth encounters higher growth barrier than ordinary layer-by-layer growth. Here, an assumption is proposed that the incomplete crystal possesses a "potential of morphology repair", which drives the thin surface layers growing to repair itself into complete form. This assumption is confirmed to some extent by a thin surface layer fragments experiment. The experiment implies that thin surface layer is the same as the ordinary crystal seed once separated from incomplete crystal, and its growth rate is one order slower than in incomplete crystal.KDP raw material (purity of 99.9%, Sinopharm Chemical Reagent Co., Ltd., Shanghai) and extra-pure water (resistance of 18.2 M ) were used for the solution preparation. The solution was filtered through filters with pore size of 0.1 µm and then overheated at a temperature of 65°C for 24 h. The temperature of crystallizer was controlled by a thermostat with accuracy of ±0.05°C. Supersaturation σ was created by temperature reduction and expressed in relative units, σ = (C − C 0 )/C 0 , where C and C 0 are the real and the equilibrium concentrations, respectively.

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Experimental Research on the Regeneration of Incomplete Crystallographic KH₂PO₄ Crystal Enclosed by Singular Face

Wang

Xiao

2019

Crystal Research and Technology

View full text Add to dashboard Cite

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Specific Self‐Repairing by Morphology Prejudging

Wang

et al. 2019

Crystal Research and Technology

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The thin surface layer growth during the regeneration of incomplete potassium dihydrogen phosphate crystal is more perplexing than the ordinary layer‐by‐layer growth. In a previous paper, the driving force of the thin surface layer growth was discussed; the present paper focuses on the regeneration process and final regeneration morphology. Based on the analysis of thin surface layer area per unit repaired volume, it is found that convex polyhedron is more advantageous than concave polyhedron. It is also found that the general morphology of repaired incomplete crystal is convex polyhedron of minimum volume covered by singular surfaces. The most important thing is, numbers of regeneration details suggest that the incomplete crystal achieves the self‐repairing by morphology prejudging.

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Numerical simulation of the hydrodynamics and mass transfer in the capping of large size Z-cut plates

Wang

et al. 2019

Journal of Crystal Growth

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Investigation on the regeneration of Z‐cut KDP crystals

Cited by 4 publications

References 13 publications

Experimental Research on the Regeneration of Incomplete Crystallographic KH₂PO₄ Crystal Enclosed by Singular Face

Experimental Research on the Regeneration of Incomplete Crystallographic KH₂PO₄ Crystal Enclosed by Singular Face

Specific Self‐Repairing by Morphology Prejudging

Numerical simulation of the hydrodynamics and mass transfer in the capping of large size Z-cut plates

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Investigation on the regeneration of Z‐cut KDP crystals

Cited by 4 publications

References 13 publications

Experimental Research on the Regeneration of Incomplete Crystallographic KH2PO4 Crystal Enclosed by Singular Face

Experimental Research on the Regeneration of Incomplete Crystallographic KH2PO4 Crystal Enclosed by Singular Face

Specific Self‐Repairing by Morphology Prejudging

Numerical simulation of the hydrodynamics and mass transfer in the capping of large size Z-cut plates

Contact Info

Product

Resources

About

Experimental Research on the Regeneration of Incomplete Crystallographic KH₂PO₄ Crystal Enclosed by Singular Face

Experimental Research on the Regeneration of Incomplete Crystallographic KH₂PO₄ Crystal Enclosed by Singular Face