三氟甲烷磺酸稀土盐对聚丙烯热稳定性的影响及机理

doi:10.7503/cjcu20180727

高等学校化学学报 ›› 2019, Vol. 40 ›› Issue (6): 1333.doi: 10.7503/cjcu20180727

• 高分子化学 • 上一篇

三氟甲烷磺酸稀土盐对聚丙烯热稳定性的影响及机理

冉诗雅, 沈海峰, 李晓楠, 王子路, 郭正虹(), 方征平

浙江大学宁波理工学院, 高分子材料与工程研究所, 宁波 315100

收稿日期:2018-10-26 出版日期:2019-06-10 发布日期:2019-06-01
作者简介:
联系人简介: 郭正虹, 女, 博士, 副教授, 主要从事阻燃高分子材料和高分子合金研究. E-mail: guozhenghong@nit.zju.edu.cn
基金资助:
国家自然科学基金(批准号: 51703197, 51673173)、浙江省教育厅一般项目(批准号: Y201738757)、宁波市自然科学基金(批准号: 2018A610112)和宁波市科技创新团队项目(批准号: 2015B11005)资助.

Effect and Mechanism of Rare Earth Trifluoromethanesulfonate on the Thermal Stability of Polypropylene^†

RAN Shiya, SHEN Haifeng, LI Xiaonan, WANG Zilu, GUO Zhenghong(), FANG Zhengping

Laboratory of Polymer Materials and Engineering, Ningbo Institute of Technology, Zhejiang University, Ningbo 315100, China

Received:2018-10-26 Online:2019-06-10 Published:2019-06-01
Supported by:
† Supported by the National Natural Science Foundation of China(Nos.51703197, 51673173), the General Project of Education of Zhejiang Province, China(No.Y201738757), the Ningbo Natural Science Foundation, China(No. 2018A610112) and the Ningbo Science and Technology Innovation Team, China(No.2015B11005).

摘要/Abstract

摘要：

通过熔融共混将三氟甲烷磺酸镱[Yb(OTf)₃]和三氟甲烷磺酸镧[La(OTf)₃]添加至聚丙烯(PP)中, 制得PP/Yb和PP/La材料, 并对其热稳定性进行表征. 热失重分析(TGA)和差示扫描量热分析(DSC)结果显示, Yb(OTf)₃和La(OTf)₃均可以显著提高聚丙烯的热稳定性. 当Yb(OTf)₃添加量仅为1%(质量分数)时, PP的起始分解温度从275 ℃提高至305 ℃, 最大分解温度从384 ℃提高至405 ℃, 160 ℃下的氧化诱导时间从12.1 min延长至43.0 min, 热焓从1907 J/g降低至483 J/g; 而PP/La1的起始分解温度、最大分解温度、 160 ℃下的氧化诱导时间和热焓分别为300 ℃, 409 ℃, 18.6 min和633 J/g. 结果表明, La(OTf)₃对聚丙烯热稳定性的改善作用弱于Yb(OTf)₃, 对2种稀土盐产生不同实验结果的原因进行分析并提出机制. 由于阴离子和阳离子的共同作用, Yb(OTf)₃和La(OTf)₃均可提高PP的热氧稳定性. La(OTf)₃中三氟甲烷磺酸根的自由基捕捉能力和稀土离子的配位能力发挥主要作用, 而Yb(OTf)₃中的稀土离子的高反应活性也起到关键作用.

关键词: 三氟甲烷磺酸稀土盐, 自由基捕获, 聚丙烯热稳定性

Abstract:

The thermal degradation of polypropylene(PP) was a free radical chain reaction, in other words, free radicals were the primary cause of combustion and degradation. Rare earth trifluoromethanesulfonate [Yb(OTf)₃ and La(OTf)₃] can interfere degradation process of PP via capturing the free radicals, thus effectively improving the thermal stability of PP. PP composites filled with two kinds of rare earth trifluoromethanesulfonates were prepared via melt blending utilizing the free-radical trapping ability of Yb(OTf)₃ and La(OTf)₃ in this paper. The thermal-stability of PP was tested by thermogravimetric analysis(TGA), differential scanning calorimetry(DSC) and thermogravimetric analysis coupled to Fourier transform infrared spectroscopy(TGA-FTIR). The results showed that Yb(OTf)₃ and La(OTf)₃ could improve the thermal-stability of PP dramatically. Simply when the addition of Yb(OTf)₃ was 1%(mass fraction), the onset degradation temperature of PP was increased from 275 ℃ to 305 ℃, the temperature corresponding to the maximum rate of mass loss increased from 384 ℃ to 405 ℃, the oxidative induction time at 160 ℃ extended from 12.1 min to 43.0 min, and the enthalpy reduced from 1907 J/g to 483 J/g, respectively. Moreover, the onset degradation temperature, the maximum rate of mass loss, the oxidative induction time at 160 ℃ and the enthalpy of PP filled with 1%(mass fraction) La(OTf)₃ were 300 ℃, 409 ℃, 18.6 min and 633 J/g, respectively. The effect of La(OTf)₃ on the thermal stability of PP was weaker than that of Yb(OTf)₃. We tried to explain these differences and then propose the possible mechanism. Due to the combined action of anions and cations, Yb(OTf)₃ and La(OTf)₃ could improve the thermal stability of PP. For La(OTf)₃, the free radical trapping ability of trifluoromethanesulfonate and the coordination ability of rare earth ions played a major role. For Yb(OTf)₃, in addition to the above reasons, the high reactivity of rare earth ions also played a key role.

Key words: Rare earth trifluoromethanesulfonate, Free-radical trapping, Thermal stability of polypropylene

中图分类号:

O631

TrendMD:

冉诗雅, 沈海峰, 李晓楠, 王子路, 郭正虹, 方征平. 三氟甲烷磺酸稀土盐对聚丙烯热稳定性的影响及机理. 高等学校化学学报, 2019, 40(6): 1333.

RAN Shiya,SHEN Haifeng,LI Xiaonan,WANG Zilu,GUO Zhenghong,FANG Zhengping. Effect and Mechanism of Rare Earth Trifluoromethanesulfonate on the Thermal Stability of Polypropylene^†. Chem. J. Chinese Universities, 2019, 40(6): 1333.

图/表 13

Fig.1 TG(A) and DTG(B) curves of PP/Yb in air a. PP; b. PP/Yb0.1; c. PP/Yb0.2; d. PP/Yb0.5; e. PP/Yb1; f. PP/Yb2; g. PP/Yb5.

Table 1 Detailed data obtained from TGA and DSC tests for PP/Yb

Sample	Air		160 ℃		180 ℃		200 ℃
Sample	T_5%/℃	T_max/℃	OIT/min	ΔH_d/(J·g^-1)	OIT/min	ΔH_d/(J·g^-1)	OIT/min	ΔH_d/(J·g^-1)
PP	275	384	12.1	1907	2.3	5534	1.0	6442
PP/Yb0.1	263	391	14.9	1353	2.5	3796	1.0	4970
PP/Yb0.2	271	398	20.6	958	2.6	2615	1.0	3932
PP/Yb0.5	289	397	30.4	718	4.0	2602	1.0	3262
PP/Yb1	305	405	43.0	483	7.4	1688	1.0	2187
PP/Yb2	314	420	36.0	314	5.0	1225	1.0	819
PP/Yb5	323	430	36.7	172	3.3	208	1.0	225

Fig.2 DSC curves of PP/Yb at 160 ℃(A), 180 ℃(B) and 200 ℃(C) a. PP; b. PP/Yb0.1; c. PP/Yb0.2; d. PP/Yb0.5; e. PP/Yb1; f. PP/Yb2; g. PP/Yb5.

Fig.3 TG(A) and DTG(B) curves of PP/La in air a. PP; b. PP/La0.1; c. PP/La0.2; d. PP/La0.5; e. PP/La1; f. PP/La2; g. PP/La5.

Fig.4 DSC curves of PP/La at 160 ℃(A), 180 ℃(B) and 200 ℃(C) a. PP; b. PP/La0.1; c. PP/La0.2; d. PP/La0.5; e. PP/La1; f. PP/La2; g. PP/La5.

Table 2 Detailed data obtained from TGA and DSC tests for PP/La

Sample	Air		160 ℃		180 ℃		200 ℃
Sample	T_5%/℃	T_max/℃	OIT/min	ΔH_d/(J·g^-1)	OIT/min	ΔH_d/(J·g^-1)	OIT/min	ΔH_d/(J·g^-1)
PP	275	384	12.1	1907	2.3	5534	1.0	6442
PP/La0.1	268	399	18.2	1560	3.8	2581	1.0	4635
PP/La0.2	283	406	23.7	924	3.3	2907	1.0	3516
PP/La0.5	296	414	28.5	616	5.8	2429	1.0	2716
PP/La1	300	409	18.6	633	4.1	1565	1.0	2250
PP/La2	303	425	18.6	623	2.7	1673	1.0	2593
PP/La5	301	423	16.7	445	3.2	1094	1.0	1978

Fig.5 TG(A) and DTG(B) curves of PP(a), Yb(OTf)3(b) and La(OTf)3(c) in air

Fig.6 FTIR spectra for Yb(OTf)3(a) and gases evolved from Yb(OTf)3 in air at 380 ℃(b), 410 ℃(c), 450 ℃(d) and 470 ℃(e)

Fig.7 FTIR spectra of total gases evolved from PP(A), PP/Yb0.5(B), PP/Yb1(C), PP/Yb2(D) and PP/La0.5(E), PP/La1(F) and PP/La2(G) in air

Fig.8 FTIR spectra of total gases(A), hydrocarbons(B), CO2(C), CO(D) and carbonyl compounds(E) evolved from PP/Yb in air at 2965 cm-1(B), 2357 cm-1(C), 2179 cm-1(D) and 1730 cm-1(E) a. PP; b. PP/Yb0.5l c. PP/Yb1; d. PP/Yb2.

Fig.9 FTIR spectra of total gases(A), hydrocarbons(B), CO2(C), CO(D) and carbonyl compounds(E) evolved from PP/La in air at 2965 cm-1(B), 2357 cm-1(C), 2179 cm-1(D) and 1730 cm-1(E) a. PP; b. PP/La0.5l c. PP/La1; d. PP/La2.

Fig.10 Changes of torque with processing time for PP(a), PP/Yb1(b) and PP/La1(c)

Fig.11 Activation energy versus RE mass fraction curves of PP/Yb(a) and PP/La(b)

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三氟甲烷磺酸稀土盐对聚丙烯热稳定性的影响及机理

Effect and Mechanism of Rare Earth Trifluoromethanesulfonate on the Thermal Stability of Polypropylene^†

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三氟甲烷磺酸稀土盐对聚丙烯热稳定性的影响及机理

Effect and Mechanism of Rare Earth Trifluoromethanesulfonate on the Thermal Stability of Polypropylene†

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Effect and Mechanism of Rare Earth Trifluoromethanesulfonate on the Thermal Stability of Polypropylene^†