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第 10 期刘雯雯，等: 改性乙二胺/氯化铜复合材料的制备及其温敏变色性能 ·2045·

图 9 中改性乙二胺/氯化铜复合材料颜色在 60 s 参考文献：
完成由无色向黄色的转变，加热到 360 s 时变为蓝 [1] Zhang Lexian (张乐显). Preparation of reversible thermochromic
materials and their application in anti-counterfeiting[D].Wuhan:
色。由无色转变为黄色的过程中，0~60 s 内 b*值逐
Huazhong University of Science and Technology (华中科技大学), 2009.
渐增大，随着盐酸用量的增加，氢离子和氯离子的 [2] Zhang Tuanhong (张团红), Hu Xiaoling (胡小玲), Guan Ping (管萍), et
al. Mechanisim and application of reversible thermochromatic materials[J].
浓度增加，颜色逐渐变深，盐酸体积为 6 mL 时，b*
Paint Coating and Plating (涂料涂装与电镀), 2006, (4): 15-20.
最大，达到 63，盐酸量继续增大后 b*值反而降低； [3] Zhu Chuanfang ( 朱传方 ), Xu Hanhong ( 徐汉红 ). Research
development of reversible thermochromic compounds[J]. Chemical
由黄色转变为蓝色的过程中，b*值逐步减小，对比 Progress (化学进展), 2001, 13(4): 261-267.
120 和 180 s 的 b*值可以看出，盐酸体积为 6 mL 时， [4] Neebe M, Rhinow D, Schromczyk N, et al. Thermochromism of
bacteriorhodopsin and its pH dependence[J]. Journal of Physical
b*值下降最大，由 56 下降到 37，低于或高于 6 mL Chemistry B, 2008, 112(23): 6946-6951.
盐酸的复合材料变色均不明显。360 s 时复合材料完 [5] Jin Y, Bai Y M, Zhu Y N, et al. Thermosensitive luminous fiber
based on reversible thermochromic crystal violet lactone pigment[J].
全变为蓝色，盐酸体积为 6 mL 时 b*值最低，为11， Dyes and Pigments, 2017, 146: 567-575.
向蓝色的转变较明显，盐酸体积为 8 mL 时 b*值最 [6] Kai S, Christoph A R, Alessandro U. VO 2 thermochromic
metamaterial- based smart optical solar reflector[J]. ACS Photonics,
高。表明一定量的盐酸可加快复合材料的变色时间， 2018, 5(6): 2280-2286.
且颜色变化程度较大。 [7] Lin J, Lai M L, Dou L T, et al. Thermochromic halide perovskite
solar cells[J]. Nature Materials, 2018, 17(3): 261-267.
[8] Chen Chunxin (陈纯馨),Chen Xi (陈忻), Liu Aiwen (刘爱文), et al.
表 2 不同盐酸添加量的改性乙二胺/氯化铜复合材料温 Development of high temperature reversible thermopaint[J]. New
Chemical Materials (化工新型材料), 2004, 32(12): 50-52, 57.
敏变色情况 [9] Ge Jingyuan (葛婧媛), Yang Wenfang (杨文芳). Application of color
Table 2 Thermosensitive discoloration of modified changing materials on textiles[J]. Dyeing and Finishing Technology
ethylenediamine/copper chloride composites (染整技术), 2007, 29(10): 5-9.
with different hydrochloric acid additions [10] Zhang Azhen (张阿真), Zheng Ruiping (郑瑞平), Bai Yanyan (柏妍
妍). Reversible thermochromic material and its application in textile
盐酸添加量/mL 改性乙二胺/氯化铜复合材料温敏变色情况
and garment[J]. Western Leather (西部皮革), 2017, 39(18): 4.
[11] Vukoje M, Miljanic S, Hrenovic J, et al. Thermochromic ink-paper
3 interactions and their role in biodegradation of UV curable prints[J].
Cellulose, 2018, 25(10): 6121-6138.
[12] Mohammed I K, Woomin J, Jong M K. Functional materials and
systems for rewritable paper[J]. Advanced Materials, 2018, 30(15):
4
1705310. DOI: 10.1002/adma.201705310
[13] Li B, Fan H T, Zang S Q, et al. Metal-containing crystalline
luminescent thermochromic materials[J].Coordination Chemistry
5 Reviews, 2018, 337: 307-329.
[14] Salvio S G, Nayarassery N A, Gábor M, et al. Spin-crossover in an
exfoliated 2D coordination polymer and its implementation in
6 thermochromic films[J]. ACS Appl Nano Mater, 2018, 1(6): 2662-2668.
[15] Zhu J T, Zhou Y J, Wang B B, et al. Vanadium Dioxide nanoparticle-
based thermochromic smart coating: high luminous transmittance,
excellent solar regulation efficiency, and near room temperature phase
7
transition[J]. ACS Appl Mater Interf, 2015, 7(50): 27796-27803.
[16] Chen R, Miao L, Cheng H L, et al. One-step hydrothermal synthesis
of V 1xW xO 2 (M/R) nanorods with superior doping efficiency and
8 thermochromic properties[J]. Journal of Materials Chemistry A,
2015, 3(7): 3726-3738.
[17] Yan Q, Yuan J Y, Kang Y, et al. Dual-sensing porphyrin-containing
copolymer nanosensor as full-spectrum colorimeter and ultra- sensitive
3 结论 thermometer[J]. Chemical Communications, 2010, 46 (16): 2781-2783.
[18] Akihiko T, Tsuda S, Shigeru Y, et al. A novel supramolecular
multicolor thermometer by self-assembly of a π-extended zinc
利用 TEOS 水解改性乙二胺氯化铜络合物制备 porphyrin complex[J]. Journal of the American Chemical Society,
2003, 125(51): 15722-15723.
具有温敏连续变色性能的改性乙二胺/氯化铜复合
[19] Gardener M, Perry C C. A new mechanism of thermochromism for silica
材料，提高了复合材料的热稳定性。盐酸中的水分 sol-gel materials[J]. Monatshefte Für Chemie, 2003, 134(3): 381-385.
[20] Han Qingfei (韩庆飞). Synthesis, characterization and electrochemistry
子为复合材料中铜离子的主要配位体，随着温度升
of A 2B corroles[D]. Zhenjiang: Jiangsu university (江苏大学), 2014.
高，氯离子也参与配位，酸的浓度增加，促进复合 [21] Chen Ling (陈玲), Yang Xiaolan (杨小兰), Zhong Guoqing (钟国
清). Synthesis and characterization of copper and nickel complexes
材料的颜色转变。改性乙二胺/氯化铜复合材料在
of thiophene-containing bissalicylaldehyde Schiff base[J]. Fine
120 ℃处水配体被氯离子取代，颜色由无色变为黄 Chemicals (精细化工), 2016, 33(7):820-824.
[22] Shen Yiding (沈一丁), Zhao Jing (赵静), Lai Xiaojuan (赖小娟).
色，当温度升高到 160 ℃时，复合材料中氮配体数
Preparation and characterization of waterborne polyurethane/
量增加，同时由于氯离子不稳定，水分子重新与铜 colloidal silica hybrid coatings[J]. Fine Chemicals (精细化工), 2010,
27(12): 1161-1165.
离子进行配位，使改性乙二胺/氯化铜复合材料颜色
[23] Wei Ting (魏婷), Guo Weihong (郭卫红), Song Dandan (宋丹丹),等.
转变为蓝色。因此改性乙二胺/氯化铜复合材料具有 Study on preparation and performance of SiO 2-based phase change
composites[J]. New Chemical Materials (化工新型材料), 2015,
良好的温度感应，有较好的应用潜力。 43(2): 60-62.

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