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China Surfactant Detergent & Cosmetics ›› 2021, Vol. 51 ›› Issue (4): 348-355.doi: 10.3969/j.issn.1001-1803.2021.04.013
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LV Bo1(
),YAN Yong-li1(),DU Chun-bao1,ZHU Xi-zhu2,WU Chun-sheng2,YU Chang-long2
Received:2020-06-05
Revised:2021-02-25
Online:2021-04-22
Published:2021-04-27
Contact:
Yong-li YAN
E-mail:1360203441@qq.com;yylhill@163.com
CLC Number:
LV Bo,YAN Yong-li,DU Chun-bao,ZHU Xi-zhu,WU Chun-sheng,YU Chang-long. Research progress in effects of micro- and nanocrystals on the foam formation and stability[J].China Surfactant Detergent & Cosmetics, 2021, 51(4): 348-355.
Fig. 1
Schematic diagram of foam formation mechanism of surface modified crystal particles[10]"
Fig. 2
Polarizing structure of crystal particles formed by different systems: Water/sodium chloride crystallization[10](a); calcium carbonate nanocrystals[11](b) ; crystallization of liquid paraffin/monodecyl glyceride[17](c); crystallization of liquid paraffin/glyceryl monolaurate[17](d); sunflower oil/myristic acid crystallization[20](e); sunflower seed oil/octadecanol crystallization[21](f); coconut oil self-assembled crystal[26](g); sunflower oil/monoglyceride crystallization[38](h)"
Fig. 3
Schematic diagram of foam formation mechanism of grease self-assembled crystals"
Fig. 4
Foaming properties of 4% fat crystal and 96% salad oil under different crystallization conditions[25]"
Fig. 5
Foams formed by the fatty alcohol crystal particles at 20 ℃ (a) and the state of the system after standing inverted for 30 min[22] (b)"
Fig. 6
Schematic diagram of stabilization mechanism of crystal particles to foam[21]"
Fig. 7
Polarizing structure of different foam systems: stable foam of chitin nanocrystals with a concentration of 1% at room temperature[14](a); foam formed by monostearate glyceride and sunflower oil at fixed concentrations[38](25 ℃(b); 35 ℃(c); 45 ℃(d))"
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