• Journal of the Korean Ceramic Society
• /
• v.41 no.6
• /
• pp.425-429
• /
• 2004

[DEACOOH]-Montmorillonite intercalations complex obtained from Na-Montmorillonite and 10-Carboxy-n-decyldimethylethylammonium bromide (organic cation) was reacted with the monomer ($\varepsilon$-caprolactone) to achieve the [DEACOOH]-$\varepsilon$-caprolactone-Montmorillonite intercalations complex. From this intercalations complex Montmorillonite/Polycaprolactone nanocomposites in which montmorillonite (inorganic polymer) is chemically linked with the polycaprolactone (organic polymer) were formed at 240$^{\circ}C$ by three different methods such as in stoichiometric amounts between monomer and organic cation, in excess of only the monomer and in excess of both organic cation and monomer. The products obtained after polymerization were analyzed with X-ray diffractometer and TEM.

• Journal of the Korean Ceramic Society
• /
• v.43 no.4 s.287
• /
• pp.207-212
• /
• 2006

[ ${\varepsilon}-caprolactam$ ] was polymerized in the layers of the [DEACOOH]-Montmorillonite intercalations complex at high temperatures ranging from 250% to 260% formed from Na-Montmorillonite and 10-Carboxy-n-decyldimethylethylammonium bromide to achieve [DEACOOH]-Polycaprolactam-Montmorillonite, in which an inorganic polymer (montmorillonite) is chemically combined with an organic polymer (polycaprolactam). The results of X-ray and IR analyses for the samples obtained after polymerization showed that the polymerization reaction was successfully accomplished. For the purpose of studying the polymeric reaction product more precisely, the polymerized product was separated from the silicate layers and analyzed with an X-ray diffractometer and an IR-spectrometer. A comparison of the results of the X-ray and IR analyses of the separated polymer and the polymer that was synthesized by the reaction of ${\varepsilon}-caprolactam$ solely with the organic cation without montmorillonite showed that the obtained both polymers are identical compounds.

• Journal of the Korean Ceramic Society
• /
• v.44 no.2 s.297
• /
• pp.71-78
• /
• 2007

A [TEACOOH]-Montmorillonite intercalations complex obtained from Na-Montmorillonite and 10-Carboxy-n-triethylammonium bromide was used to attempt the polymerization of ${\varepsilon}$-caprolactone between the layer spaces of the intercalations complex to achieve Montmorillonite-Polycaprolactone nanocomposites in which the inorganic material (montmorillonite) is chemically combined with the organic polymer (polycaprolactone). The results of X-ray-, IR-, and TEM-analyses for samples obtained after polymerization showed that a polycondensation reaction was successfully produced. For a more precise investigation of the polymeric reaction products the polymerized products were separated from the silicate layers and analyzed with an IR-spectrometer. A comparison of the results of the IR-analyses of the separated polymer with that of the polymer synthesized by the reaction of ${\varepsilon}$-caprolactone with only the organic cation and without montmorillonite showed that the two obtained polymers are the same compound.

• Journal of the Korean Ceramic Society
• /
• v.42 no.4
• /
• pp.224-231
• /
• 2005

The polymerization of $\varepsilon-caprolactone$ in the layers of the [DEACOOH]-Montmorillonite intercalations complex was attempted using 10-Carboxy-n-decyldimethylethylammonium bromide and Na-Montmorillonite to achieve [DEACOOH]-Polycaprolactone-Montmorillonite in which the inorganic material (montmorillonite) and the organic material (polycaprolactone) are chemically linked each other. The results of X-ray- and IR-analysis for the samples obtained after polymerization showed that the polymerization reaction has been successfully accomplished. In order to study the polymeric reaction products more precisely we have separated the polymerized product from the silicate layers and analyzed it with X-ray diffractometer, IR-spectrometer and TEM. The comparison of the results of X-ray- and IR-analysis for the separated polymer with them for the polymer which was synthesized by the reaction of $\varepsilon-caprolactone$ only with the organic cation without montmorillonite showed that the obtained both polymers are the same compounds.

• The Journal of Engineering Research
• /
• v.7 no.1
• /
• pp.79-87
• /
• 2005

[TEACOOH]-Montmorillonite intercalations complex obtained from Na-Montmorillonite and 10-Carboxy-n-decyldimethylethylammonium bromide(organic cation) was reacted with the monomer($\varepsilon$-caprolactone) to achieve the [TEACOOH]-$\varepsilon$-caprolactone-Montmorillonite intercalations complex. From intercalations complex Montmorillonite/Polycaprolactone Nanocomposite in which montmorillonite(inorganic material) is chemically linked with the polycaprolactone(organic polymer) was formed at $220^{\circ}C$ for 48 h. The basal spacing for the sample obtained after polymerization, extraction with methanol and dried at $65^{\circ}C$ in high vacuum for 24 h was 50.7 $\AA$.

• Journal of the Korean Ceramic Society
• /
• v.30 no.4
• /
• pp.259-264
• /
• 1993

In this research, the organic tenside R11OSO3- with long alkyl-chain was synthesized, and the intercalationscomplexes fo montmorillonite were formed by the substitution of metallic cation in the montmorilonite by the synthesized organic tenside in following two methods, and the behaviors of the tenside R11OSO3- in the interlamellar space of montmorillonite were studied udner various conditions: 1) In order to protonize the sulfate group of R11OSO3-, the H3O-Montomorillonite, which acts as acid, was synthesized. And then, the organic tenside was intercalated in the interlamellar space of this H3O-Montomorillonite. And thus, the intercalations-complex of R11S-H3O-Montomorillonite was formed. The basal spacing obtained was about 33.84$\AA$. 2) The betaine compound R11OSO3- as a neutral molecule was direct intercalated in the interlamellar space of Na-Montmorillonite under water, and the intercalations-complexes of R11S-H2O-Montmorillonite was synthesized. In this case, the based spacing of bout 23.62$\AA$ was obtained.

• The Journal of Natural Sciences
• /
• v.5 no.1
• /
• pp.77-86
• /
• 1992

By cation-exchange-reaction long-chain organic cationic tensides can be intercalated in the montmorillonite layer space, and thus intercalations-complexes of montmorillonite with different properties of materials can be obtained. Such intercalations-complexes are finding strong technical appliances in many areas and are also used very often as model-systems for studying behaviors of materials. Therefore in this research intercalations-complexes of montmorillonite with organic cationic tensides ad model-systems were synthesized and their behabiors under various different conditions were studied.

• Proceedings of the Korean Fiber Society Conference
• /
• 2007.11a
• /
• pp.205-206
• /
• 2007

See Full Text

• Journal of the Korean Ceramic Society
• /
• v.36 no.2
• /
• pp.151-158
• /
• 1999

$\varepsilon$-Caprolactame as organic monomer was intercalated in the interlayer space of montmorillonite and polymerized by polymerization reaction so that the inorganic polymer and organic polymer could be combined each other by chemical bonding. The results of X-ray and IR analysis showed that the polymerization reaction of $\varepsilon$-caprolactame between the interlayer spaces has been performed sucessfully. In order to study polymeric reaction product in detail we have isolated the polymerized material from the interlayer space and analyzed it by X-ray diffractometer and IR-Spectrocopy. The comparison of these results with them of the analyses for thee pure polymer which has been synthesized by polymeric reaction of $\varepsilon$-carolactame without montmorillonite showed that the obtained both polymeric materials are the same compounds.

• Proceedings of the Korea Association of Crystal Growth Conference
• /
• 1996.06b
• /
• pp.223-237
• /
• 1996

플라스틱재료의 강도, 인성, 경직성, 탄성 등과 같은 기계적 특성을 개선시켜 주기 위해 kaoline, talc, sand, quartz 등과 같은 규산염을 첨가하여 복합재료를 만들고자 하는 연구가 상당히 활발하다. 이와 같이 다양한 규산염이 복합재료의 강화재 또는 첨가제로 사용되는 반면에, 규산염가운데 공업적으로 이용도가 가장 높은 montmorillonite는 아직도 복합재료의 강화재로 폭 넓게 이용되고 있지 못한 실정이다. 이론적으로 볼 때, 높은 분자량을 지니는 무기고분자 (예; inorganic montmorillonite)와 유기고분자 (organic polymer)를 gkadbk는 실질적인 무기-유기 결합물질의 생성이 가능할 수 있으며, 이에 대한 연구 또한 시도되고 있다. 이렇게 해서 얻게 되는 무기-유기 복합체, 즉 montmorillonite로 강화된 플라스틱 복합재료 bumper를 사용함으로써 접촉 또는 충돌시 충격완화의 효과를 가져 올 수 있어 안정성이 좋아지고, 내파괴성이 높기 때문에 비강화 플라스틱재료보다 더 오래 사용할 수 있으므로 경제성이 좋을 뿐만 아니라, 폐품의 감소로 인해 환경보호에도 일익을 담당할 수 있다. 따라서, 본 연구에서는 이러한 montmorillonite강화 플라스틱 복합체를 얻기 위해 우선 무기-유기 고분자물질의 형성이 가능한가를 조사분석하였다. 이를 위해 먼저 amontmorillonite의 층사이에서 화학반응이 수행될 수 있는 충분한 공간을 얻고자 Na-Montmorillonite 층사이의 Na+-이온을 긴 알킬사슬을 취하는 유기 양이온으로 치환시켜 주었다; 이렇게 해서 얻은 유기양이온-몬트모릴로나이트 층간화합물 (Organic cation-Montmorillonite Intercalations-complex)내에 유기 단분자 (organic monomer)를 추가적으로 삽입시킨 후, montmorilonite의 층내에서 증합반응시켜 고분자화해 줌으로써 무기고분자와 유기고분자가 서로 결합된 무기-유기고분자 결합물질을 형성하고자 하였다. X-선 및 IR-분석결과 층내에서의 유기단분자의 고분자화 반응이 성공적으로 이루어 졌음이 입증되었다.