Adv Search
Volume 8 Issue 2
Jun.  2006
Turn off MathJax
Article Contents
Abstract
References
Related Articles
HUANG Yi-lan, QI Li-jian. Spiral Nucleating Growth of Nacreous Layer on Pteria Penguin and Blister Pearl Controlled by Organic Matrix[J]. Journal of Gems & Gemmology, 2006, 8(2): 20-24.
Citation: HUANG Yi-lan, QI Li-jian. Spiral Nucleating Growth of Nacreous Layer on Pteria Penguin and Blister Pearl Controlled by Organic Matrix[J]. Journal of Gems & Gemmology, 2006, 8(2): 20-24.
shu

Spiral Nucleating Growth of Nacreous Layer on Pteria Penguin and Blister Pearl Controlled by Organic Matrix

  • Gemmological Institute, China University of Geosciences, Wuhan 430074, China

More Information
  • Received Date: April 27, 2006
    Graphical Abstract
    • Abstract
  • The surface morphology of the nacreous layer on different parts of Pteria Penguin and blister pearl from Sanya, Hainan Province, are observed directly by using environmental scanning electron microscope. The samples are dipped in hydrochloric acid (0.5%) and EDTA for part or complete decalcification. The results indicate that the organic film in the nacreous layer rigorously controls the spiral nucleating growth and orientation of crystallization, which offers an effective growth centre for the growth of aragonite or calcite crystallite. As a result, the spiral growth structure of nacreous layer is produced by the periodically alternative growth of aragonite and organic matrix in the time and space. The formation of the nacreous layer of Pteria Penguin results from the initial spiral nucleating growth controlled by the organic film. The organic film directly induces the nucleating of aragonite crystallite to be spiral growth in the nacreous layer, that makes aragonite and organic matrix grow alternatively, and controls the orientation of crystallization and the mode of self-assembly of aragonite crystallite and finally results in the formation of the spiral growth layer.
    • FullText(HTML)
    • References (9)
  • [1]
    赵珊茸, 谭劲. 菊花生长模型的分形特点及其物理意义[J]. 地球科学, 1999, 24(1):69-73.
    [2]
    黄艺兰, 亓利剑. 珍珠层螺旋生长结构及其生长机制[J]. 宝石和宝石学杂志, 2005, 7(3):14-19.
    [3]
    Sudo S, Fujikawa T, Nagakura T, et al. Structures of mollusc shell framwork proteins[J]. Nature, 1997, 387(5):563-564.
    [4]
    Kono M, Hayashi N, Samata T. Molecular mechanism of the nacreous layer formation in Pinctada Maxi ma[J]. Biochem Biophys Res Commun, 2000, 269(1):213-218.
    [5]
    Hou WT, Feng Q L. Crystal orientation preference and formation mechanism of nacreous layer in mussel[J]. Journal of Crystal Growth, 2003, 258(3-4):402-408.
    [6]
    张刚生, 谢先德. 贝壳珍珠层微结构及成因理论[J]. 矿物岩石, 2000, 20(1):11-16.
    [7]
    Weiner S. Soluble protein of the organic matrix of mollusk shells:Apotential template for shell formation[J]. Science, 1975, 190(5):987-989.
    [8]
    Watabe N, Wilbur K M. Influence of the organic matrix on crystal type in mollusks[J]. Nature, 1960, 188:334.
    [9]
    袁耀初, 刘勇刚, 楼如云, 等. 2000年夏季南海环流的改进逆方法计算[J]. 海洋学报, 2004, 26(1):1-12.
    • Related Articles

  • Related Articles

    [1]ZHAN Yuqian, YANG Jiong, QIU Zhili, ZHENG Xinyu, YE Xu. Exploration on the Origin of Some Serpentine Jade Based on Non-Destructive and Micro-Destructive Test[J]. Journal of Gems & Gemmology, 2024, 26(S1): 125-127.
    [2]PENG Yufan, YANG Jiong, SHAO Jing, QIU Zhili, ZHANG Yuefeng, YE Xu, QU Pan, GAO Zhenli, LUO Zhengchen. fsLA-ICP-MS Analysis of Siliceous Stone Arrowheads at Shimao Site[J]. Journal of Gems & Gemmology, 2024, 26(S1): 119-121.
    [3]LIAO Xiuhong, HU Zhaochu, LIU Dan, ZENG Xianli, FENG Lanping, ZHANG Wen. Single-Second Pulse LA-MC-ICP-MS Analysis of Sr Isotope: Application to the Quasi "Non-Destructive" Discrimination between Seawater Cultured Pearl and Freshwater Cultured Pearl[J]. Journal of Gems & Gemmology, 2024, 26(S1): 89-90.
    [4]ZHENG Xinyu, GU Xianzi, HUANG Xiang, QIU Zhili, ZHANG Yuefeng, HUANG Xiangtong. Materials Origin Traceability of Serpentine Jade Artifacts Unearthed from Fuquanshan Site[J]. Journal of Gems & Gemmology, 2024, 26(3): 1-9. DOI: 10.15964/j.cnki.027jgg.2024.03.001
    [5]YU Haochi, SHU Jun, LU Zhuo, LIU Xinxin, ZHOU Qishen. Chemical Composition and Spectral Characteristic of Blue Tourmaline from Yunnan Province, China[J]. Journal of Gems & Gemmology, 2023, 25(5): 54-64. DOI: 10.15964/j.cnki.027jgg.2023.05.006
    [6]ZHAO Xuejiao, LI Liping, CHEN Zhaomin, LI Siqi. Spectrum and Chemical Composition Characteristics between White "Freshwater Akoya Pearls" and Akoya Pearls[J]. Journal of Gems & Gemmology, 2023, 25(2): 32-41. DOI: 10.15964/j.cnki.027jgg.2023.02.005
    [7]YU Xiaoyan, LONG Zhengyu, ZHANG Yi, LIU Fei, WANG Guangya, GUO Hongshu, ZHENG Yuyu. In-Situ Micro-Analysis and Application in Gemmology Based on LA-(MC)-ICP-MS[J]. Journal of Gems & Gemmology, 2022, 24(5): 134-145. DOI: 10.15964/j.cnki.027jgg.2022.05.013
    [8]PEI Jing-cheng, XIE Hao, HE Zheng-yong. Study on Gemmological and Mineral Characteristics of Phosphosiderite[J]. Journal of Gems & Gemmology, 2012, 14(4): 40-43.
    [9]LIAO Guan-lin, ZHOU Zheng-yu, LIAO Zong-ting. XRD and IR Spectra Study on Green Nephrite from Taiwan[J]. Journal of Gems & Gemmology, 2012, 14(4): 23-29.
    [10]PEI Jing-cheng, XIE Hao, SUN Chun-lin. Study on Gemmological Characteristics of Red Feldspar[J]. Journal of Gems & Gemmology, 2009, 11(3): 11-14.

Catalog

    Get Citation
    PDF
    XML

    Article Metrics

    Article views (25) PDF downloads (1) Cited by()
    Related
    Email alert RSS
    二维码

    Supported by Beijing Renhe Information Technology Co., Ltd. Baidu Analytics

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return