Self-assembly in the growth of precious opal

A. M. Stewart; Lewis T. Chadderton; Brian R. Senior

doi:10.1016/j.jcrysgro.2009.09.042

Self-assembly in the growth of precious opal

A. M. Stewart, Lewis T. Chadderton^*, Brian R. Senior

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

It is proposed that primary nucleation of amorphous microspherulites of hydrated silica in natural proto-precious-opal can be followed by a long range superlattice ordering process by means of electrostatic self-assembly. Necessary conditions in the thermodynamics are a high surface charge density on microspherulite surfaces, a long Debye length and an appropriate number density of nucleation centres. A further chemical requirement is a high alkaline environmental pH ∼9-10. It is also proposed that the characteristic concentric spherical shell-like structure of spherulites, centred on primary nuclei, are due to sequential deposition of intrinsic salts, which precipitate out when the corresponding solubility limits in the liquid are successively exceeded. It can be that the better-known sedimentation of microspherulites under gravity only plays part in the final stabilization period of overall growth. Crown

Original language	English
Pages (from-to)	391-396
Number of pages	6
Journal	Journal of Crystal Growth
Volume	312
Issue number	3
DOIs	https://doi.org/10.1016/j.jcrysgro.2009.09.042
Publication status	Published - 15 Jan 2010

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10.1016/j.jcrysgro.2009.09.042

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title = "Self-assembly in the growth of precious opal",

abstract = "It is proposed that primary nucleation of amorphous microspherulites of hydrated silica in natural proto-precious-opal can be followed by a long range superlattice ordering process by means of electrostatic self-assembly. Necessary conditions in the thermodynamics are a high surface charge density on microspherulite surfaces, a long Debye length and an appropriate number density of nucleation centres. A further chemical requirement is a high alkaline environmental pH ∼9-10. It is also proposed that the characteristic concentric spherical shell-like structure of spherulites, centred on primary nuclei, are due to sequential deposition of intrinsic salts, which precipitate out when the corresponding solubility limits in the liquid are successively exceeded. It can be that the better-known sedimentation of microspherulites under gravity only plays part in the final stabilization period of overall growth. Crown",

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AU - Chadderton, Lewis T.

AU - Senior, Brian R.

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AB - It is proposed that primary nucleation of amorphous microspherulites of hydrated silica in natural proto-precious-opal can be followed by a long range superlattice ordering process by means of electrostatic self-assembly. Necessary conditions in the thermodynamics are a high surface charge density on microspherulite surfaces, a long Debye length and an appropriate number density of nucleation centres. A further chemical requirement is a high alkaline environmental pH ∼9-10. It is also proposed that the characteristic concentric spherical shell-like structure of spherulites, centred on primary nuclei, are due to sequential deposition of intrinsic salts, which precipitate out when the corresponding solubility limits in the liquid are successively exceeded. It can be that the better-known sedimentation of microspherulites under gravity only plays part in the final stabilization period of overall growth. Crown

KW - A1. Crystal structure

KW - A1. Growth models

KW - A1. Nucleation

KW - A2. Natural crystal growth

KW - B1. Nanomaterials

KW - B1. Silicates

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DO - 10.1016/j.jcrysgro.2009.09.042

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VL - 312

SP - 391

EP - 396

JO - Journal of Crystal Growth

JF - Journal of Crystal Growth

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ER -

Self-assembly in the growth of precious opal

Abstract

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