新型炭材料
新型炭材料
신형탄재료
New Carbon Materials
2015年
5期
459-465,383
,共8页
李琳%祁文博%王虹%张萍萍%孙美悦%王同华%李建新%曹义鸣
李琳%祁文博%王虹%張萍萍%孫美悅%王同華%李建新%曹義鳴
리림%기문박%왕홍%장평평%손미열%왕동화%리건신%조의명
聚酰亚胺%炭膜%化学结构%热解机理
聚酰亞胺%炭膜%化學結構%熱解機理
취선아알%탄막%화학결구%열해궤리
Polyimide%Carbon membrane%Chemical structure%Pyrolysis mechanism
从分子设计出发,用不同的二胺单体和相同的二酐单体合成聚酰胺酸并制备聚合物膜. 采用热重﹑热重-质谱﹑红外和X射线光电子能谱分析聚酰胺酸在热解过程中的结构变化及机理. 结果表明,在热解过程中,聚酰胺酸的热解包括4个阶段,经吸附水和吸附氧的脱除及溶剂挥发,亚胺化,交联,以及高温阶段的主链断裂﹑脱氧﹑脱氢﹑芳构化等热解过程转化为无定形炭结构. 前驱体的结构不同导致热解过程存在差异. PPD-PMDA和TMPPD-PMDA热解时所需的温度较高. 其它聚酰亚胺析出CH4﹑CO2﹑C6 H6的温度顺序为ODA-PMDA>BDAF-PMDA>BAPP-PMDA. 在700 ℃热解后,BDAF-PMDA所含的氟元素基本消失. 这表明聚酰亚胺的化学结构对炭膜的微结构有较大影响.
從分子設計齣髮,用不同的二胺單體和相同的二酐單體閤成聚酰胺痠併製備聚閤物膜. 採用熱重﹑熱重-質譜﹑紅外和X射線光電子能譜分析聚酰胺痠在熱解過程中的結構變化及機理. 結果錶明,在熱解過程中,聚酰胺痠的熱解包括4箇階段,經吸附水和吸附氧的脫除及溶劑揮髮,亞胺化,交聯,以及高溫階段的主鏈斷裂﹑脫氧﹑脫氫﹑芳構化等熱解過程轉化為無定形炭結構. 前驅體的結構不同導緻熱解過程存在差異. PPD-PMDA和TMPPD-PMDA熱解時所需的溫度較高. 其它聚酰亞胺析齣CH4﹑CO2﹑C6 H6的溫度順序為ODA-PMDA>BDAF-PMDA>BAPP-PMDA. 在700 ℃熱解後,BDAF-PMDA所含的氟元素基本消失. 這錶明聚酰亞胺的化學結構對炭膜的微結構有較大影響.
종분자설계출발,용불동적이알단체화상동적이항단체합성취선알산병제비취합물막. 채용열중﹑열중-질보﹑홍외화X사선광전자능보분석취선알산재열해과정중적결구변화급궤리. 결과표명,재열해과정중,취선알산적열해포괄4개계단,경흡부수화흡부양적탈제급용제휘발,아알화,교련,이급고온계단적주련단렬﹑탈양﹑탈경﹑방구화등열해과정전화위무정형탄결구. 전구체적결구불동도치열해과정존재차이. PPD-PMDA화TMPPD-PMDA열해시소수적온도교고. 기타취선아알석출CH4﹑CO2﹑C6 H6적온도순서위ODA-PMDA>BDAF-PMDA>BAPP-PMDA. 재700 ℃열해후,BDAF-PMDA소함적불원소기본소실. 저표명취선아알적화학결구대탄막적미결구유교대영향.
Polyimide membranes were synthesized by the polymerization of five diamines, p-phenylenediamine (PPD), 2,3,5,6-tetramethyl-1,4-phenylenediamine (TMPPD), 4,4′-oxydianiline (ODA), 4,4′-(4,4′-isopropylidenediphenyl-1,1′-diyldioxy)dian-iline (BAPP) and 4,4′-(hexafluoroisopropylidene)bis(p-phenyleneoxy) dianiline (BDAF), and the same dianhydride monomer, 1,2,4,5-benzenetetracarboxylic anhydride (PMDA). The chemical structures of the membranes pyrolyzed at different temperatures were investigated by TGA, TG-MS, FT-IR and XPS. Results indicate that there are five stages during pyrolysis:( a) the removal of the solvents, adsorbed oxygen and water, ( b) imidization, ( c) cross-linking and carbonization, which are accompanied by main chain breaking, ( d) deoxygenation and dehydrogenation, ( e) aromatization and turbostratic carbon formation. The chemical struc-ture of the precursor is the main factor that causes the great differences in chemical structures during pyrolysis. Imidization in the py-rolysis of the PPD-PMDA and TMPPD-PMDA occurs at higher temperatures than those for ODA-PMDA, BDAF-PMDA and BAPP-PMDA. The order of temperatures for the release of CH4 , CO2 and C6 H6 during the pyrolysis is ODA-PMDA>BDAF-PMDA>BAPP-PMDA. Elemental F in the BDAF-PMDA disappears after pyrolysis at 700 ℃. The chemical structures of the polyimides have a great influence on the microstructures of the carbon membranes obtained.