以苯胺(An)为单体,氨基磺酸(SA)为掺杂剂,过硫酸铵(APS)为氧化剂,采用化学氧化聚合法合成了掺杂态导电聚苯胺。考察了n(苯胺)/n(掺杂剂)、n(苯胺)/n(氧化剂)和反应时间对聚苯胺电导率的影响。结果表明,当n(An)∶n(SA)∶n(APS)=1∶6∶0.4、反应时间为6h 时,聚苯胺的电导率最高达到0.87S/cm。进一步利用灰色关联分析,定量地分析了各因素对掺杂态导电聚苯胺电导率的影响程度,得出了各因素影响电导率的大小顺序为掺杂剂、氧化剂、反应时间。并以氨基磺酸的添加量为基本建立了掺杂态导电聚苯胺电导率的灰色预测模型(灰色离散 Ver-hulst模型),预测了氨基磺酸不同添加量下的电导率,平均预测精度为97.25%。结果证明,灰色系统理论在掺杂态导电聚苯胺的电导率的预测中是可行的。
With aniline(An)as monomer,sulfamic acid(SA)as dopant,ammonium persulfate(APS)as oxi-dant,prepared doped conductive polyaniline(PANI)via chemical oxidation polymerization.We researched the effect of molar ratio of An and dopant,An and oxidant,and reaction time to the conductivity of PANI.The conductivity of PANI was to 0.87S/cm,when reaction time was 6h and n(An)∶n(SA)∶n(APS)=1∶6∶0.4.Furthermore,the extents of factors affecting the conductivity of PANI were analyzed quantitatively u-sing the grey relational analysis with the order of the dopant,oxidant,reaction time.And basing on grey predic-tion theory,the grey discrete Verhulst model of the conductivity of PANI was built with the sulfamic acid(SA) addition as base quantity by dealing with the original experiment data.The conductivity of PANI was predicted at the different sulfamic acid (SA)addition.The average accuracy was 97.25%.The application examples showed that these new methods had higher accuracy,therefore the conductivity of PANI forecasting based on grey system theory was feasible.
参考文献
| [1] | Mac Diarmid A G;Chiang J C;Richter A F et al.Poly-aniline:a new concept in conducting polymers[J].Synthetic Metals,1987,18:285-290. |
| [2] | 马荣华,王福平.Keggin结构钴取代硅钨酸盐聚苯胺掺杂材料的合成及性质[J].无机化学学报,2007(03):445-450. |
| [3] | Duan Yuping;Wu Guangli;Li Xiaogang;Ji Zhijiang;Liu Shunhua;Li Weiping .On the correlation between structural characterization and electromagnetic properties of doped polyaniline[J].Solid state sciences,2010(8):1374-1381. |
| [4] | 付志兵,唐永建,王朝阳.超声化学法合成聚苯胺及其表征[J].功能材料,2009(12):2020-2022. |
| [5] | 钟新仙,汪艳芳,王芳平,王新宇,王红强,张初华,钟镇妙.不同形貌的甲酸掺杂聚苯胺的电容性能[J].功能材料,2010(01):66-68. |
| [6] | 王学智,王秀峰,包柳,伍媛婷,江红涛,王豪.磺基水杨酸掺杂聚苯胺纳米棒的界面聚合法制备及表征[J].功能材料,2010(11):1940-1943. |
| [7] | 陈德贤,郑玉婴,张通,李宝铭.磺基水杨酸掺杂导电聚苯胺纳米材料的制备与性能研究[J].功能材料,2012(11):1373-1377. |
| [8] | 谢英男,詹自力,张红芹,蒋登高.有机磺酸掺杂聚苯胺的气敏性能[J].高校化学工程学报,2009(01):154-159. |
| [9] | 谷威,李志强,朱申敏,张荻.高能球磨法固相掺杂制备樟脑磺酸掺杂聚苯胺[J].化学学报,2008(09):1097-1101. |
| [10] | 冯辉霞,邵亮,王毅,张国宏,赵阳,邱建辉.氨基磺酸掺杂导电聚苯胺/OMMT纳米复合材料的制备与性能研究[J].功能材料,2007(10):1731-1733. |
| [11] | 刘思峰,邓聚龙.GM(1,1)模型的适用范围[J].系统工程理论与实践,2000(05):121-124. |
| [12] | 田民,刘思峰,卜志坤.灰色关联度算法模型的研究综述[J].统计与决策,2008(01):24-27. |
| [13] | 崔立志,刘思峰,李致平.灰色离散Verhulst模型Symbol[J].系统工程与电子技术,2011(03):590-593. |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%