Biomimetic Synthesis of Vaterite by N-Succinyl-O-Hydroxypropyl Sulfonated Chitosan

doi:10.11901/1005.3093.2015.073

Chinese Journal of Materials Research

2016, Vol. 30

Issue (1): 31-37 DOI: 10.11901/1005.3093.2015.073

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Biomimetic Synthesis of Vaterite by N-Succinyl-O-Hydroxypropyl Sulfonated Chitosan

CHEN Xiaodong, XIN Meihua, LI Mingchun^**(

), CHEN Zhangxu, CHEN Zhiqiang

College of Material Science and Engineering, Huaqiao University, Engineering Research Center of Environment-Friendly Functional Materials, Ministry of Education, Xiamen 361021, China

Cite this article:

CHEN Xiaodong, XIN Meihua, LI Mingchun, CHEN Zhangxu, CHEN Zhiqiang. Biomimetic Synthesis of Vaterite by N-Succinyl-O-Hydroxypropyl Sulfonated Chitosan. Chinese Journal of Materials Research, 2016, 30(1): 31-37.

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Abstract

N-succinyl-O-hydroxypropyl sulfonated chitosan (SA-HPSCS) was prepared and then characterized by FT-IR and ¹HNMR. The role of SA-HPSCS in the biomimetic synthesis of CaCO₃ was studied, while the CaCO₃ crystal produced in a pure water system was used as a reference. The influence of pH value on the morphology and crystallographic structure of CaCO₃ crystal in the SA-HPSCS system was investigated and the relevant mechanism was proposed. The results show that the calcite is the only phase of CaCO₃ crystal prepared in the pure water system, while the vaterite is dominant phase of those prepared in the SA-HPSCS system. By pH=6 the vaterite content in the prepared CaCO₃ reached 95.8%, but both the size and the content of the vaterite dropped with the increase of pH value. The results also indicate that SA-HPSCS could regulate effectively the synthesis process of the CaCO₃ crystal in terms of morphology, polymorph and dimension, and the pH value could strongly affect its regulation effect.

Key words: organic polymer materials chiosan derivatives biomimetic synthesis calcium carbonate pH response

Received: 04 February 2015

Fund: *Supported by the Key Science Projects of Fujian Province No.2009H0030, the Natural Science Foundation of Fujian Province No.2012J01396, and the Ministry of Science and Technology Personnel Service Enterprise Project No.2009GJC40030

About author: ** To whom correspondence should be addressed, Tel: (0595)22690819, E-mail: mcli@hqu.edu.cn

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	Xiaodong CHEN
	Meihua XIN
	Mingchun LI
	Zhangxu CHEN
	Zhiqiang CHEN

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https://www.cjmr.org/EN/10.11901/1005.3093.2015.073 OR https://www.cjmr.org/EN/Y2016/V30/I1/31

Fig.1 FT-IR spectra of chitosan and chitosan derivates

Fig.2 ¹H NMR spectra of chitosan derivate (a) SACS, (b) SA-HPSCS

Fig.3 pH value-dependent Zeta potential curve of SA-HPSCS

Fig.4 FT-IR spectra of calcium carbonate obtained in different system

Fig.5 XRD spectra of calcium carbonate obtained in pure water (a) and SA-HPSCS (b)

Fig.6 FESEM images of calcium carbonate in pure water (a) and SA-HPSCS (b)

Fig.7 XRD spectra of calcium carbonate at various pH

Fig.8 FESEM images of calcium carbonate at various pH, (a) pH 6, (b) pH 7, (c) pH 8, (d) pH 9, (e) pH 10

Fig.9 Schematic diagram of mechanism for synthesis of vaterite by SA-HPSCS at various pH

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