| REVIEW PAPER |
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| Flow and Mass Transfer Laws in Drying Droplets: Theory and Applications |
| HU Yinchun1, ZHANG Xuerong1, HUANG Di1, WEI Yan1, SU Xiaomei2, ZHOU Qiong3
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1 College of Mechanics, Shanxi Key Laboratory of Material Strength & Structural Impact, Taiyuan University of Technology, Taiyuan 030024;
2 China Tianchen Engineering Corporation, Tianjin 300400;
3 College of Science,China University of Petroleum-Beijing, Beijing 102200 |
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Abstract The drying of droplet is a process with heat and matter transfer. It is a process that permeates most disciplines in modern technologies and has not been fully understood. The flow and mass transfer laws in the drying droplets and their application are reviewed in this paper. It mainly includes experiments aimed at principles for typical process of droplet drying and the correspon-ding matter flow modes, film patterns from drying polymer solution droplet, composite solution droplet, and complex droplets. Meanwhile, the applications of drying droplet theory in ink-jet printing, disease diagnosis and nanomaterial preparation are briefly analyzed. Finally, present situation and future application requirements for drying droplet theory are summarized and prospected.
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Published: 10 April 2017
Online: 2018-05-08
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1 Gans B J de, Duineveld P C, Schubert U S. Inkjet printing of polymers: State of the art and future developments[J]. Adv Mater,2004,16(3):203.
2 Sirringhaus H, Kawase T, et al. High-resolution inkjet printing of all-polymer transistor circuits[J]. Science,2000,290:2123.
3 Denkov N D, Velev D, Kralchevsky P A, et al. Mechanism of formation of two-dimensional crystals from latex particles on substrates[J]. Langmuir,1992,8:3183.
4 Dimitrov A S, Dushkin C D, Yoshimura H, et al. Observations of latex particle two-dimensional-crystal nucleation in wetting films on mercury, glass, and mica[J]. Langmuir,1994,10:432.
5 Alivisatos P. Colloidal quantum dots. from scaling laws to biological applications[J]. Pure Appl Chem,2000,72(1-2):3.
6 Deegan R D, Bakajin O, et al. Capillary flow as the cause of ring stains from dried liquid drops[J]. Nature,1997,389:827.
7 Hu H, Larson R G. Marangoni effect reverses coffee-ring depositions[J]. J Phys Chem B,2006,110:7090.
8 Bormashenko E, Bormashenko Y, Pogreb R, et al. Droplet behavior on flat and textured surfaces: Co-occurrence of deegan outward flow with Marangoni solute instability[J]. J Colloid Interface Sci,2007,306(1):128.
9 Inen A C, Petrock A M, Chou T, et al. Applied surface science crystal morphology variation ininkjet-printed organic materials[J]. Appl Surf Sci,2011,258(2):827.
10 Jung Y, Kajiya T, Yamaue T, et al. Film formation kinetics in the drying process of polymer solution enclosed by bank[J]. Jpn J Appl Phys,2009, 48(3):031502-1.
11 Gu X, Wang G. Interfacial morphology and friction properties of thin PEO and PEO/PAA blend films[J]. Appl Surf Sci,2011,257(6):1952.
12 Tadashi K, Wataru K, Tohru O, et al. Controlling the drying and film formation processes of polymer solution droplets wit addition of small amount of surfactants[J]. J Phys Chem B,2009,113:15460.
13 Willmer D, Baldwin A, John D, et al. Growth of solid conical structures during multistage drying of sessile poly (ethylene oxide) droplets[J]. Phys Chem Chem Phys,2010,12:3998.
14 Kim J H, Ahn S I, Kim J H, et al. Evaporation of water droplets on polymer surfaces[J]. Langmuir,2007,23(11):6163.
15 Fang X, Li B, Petersen E, Ji Y, et al. Factors controlling the drop evaporation constant[J]. J Phys Chem B,2005,109:20554.
16 Kajiya T, Kaneko D, Doi M. Dynamical visualization of “coffee stain phenomenon” in droplets of polymer solution via fluorescent microscopy[J]. Langmuir,2008,24(21):12369.
17 Xu X F, Luo J. Marangoni flow in an evaporating water droplet[J]. Appl Phys Lett,2007,91(12):124102.
18 Xu Xuefeng.The flow in the evaporating water droplets[D]. Beijing: Tsinghua University,2007(in Chinese).
徐学锋. 蒸发水滴中的液体流动特性研究[D].北京:清华大学,2007.
19 Buffone C, Sefiane K. Investigation of thermocapillary convective patterns and their role in the enhancement of evaporation from pores[J]. Int J Multiphase Flow,2004,30(9):1071.
20 Buffone C, Sefiane K, Christy J R E. Experimental investigation of self-induced thermocapillary convection for an evaporating meniscus in capillary tubes using micro-particle image velocimetry[J]. Phys Fluids,2005, 17(5):052104.
21 He Q, Hallinan K P. A new particle image velocimetry technique for three-dimensional full field fluid flow measurement in evaporating films[J]. Experimental Thermal Fluid Sci,1998,17(3):230.
22 Hegseth J J, Rashidnia N, Chai A. Natural convection in droplet evaporation[J]. Phys Rev E,1996,54(2):1640.
23 Steinchen A, Sefiane K. Self-organised Marangoni motion at evaporating drops or in capillary menisci-thermohydro dynamical model[J]. J Non-Equilibrium Thermodynam,2005,30(1):39.
24 Hu H, Larson R G. Analysis of the microfluid flow in an evaporating sessile droplet[J]. Langmuir,2005,21:3963.
25 Hu H, Larson R G. Analysis of the effects of marangoni stresses on the microflow in an evaporating sessile droplet[J]. Langmuir,2005,21:3972.
26 Meysam R Barmi, Carl D Meinhart. Convective flows in evaporating sessile droplets[J]. J Phys Chem B,2014,118:2414.
27 Kajiya T, Monteux C, et al. Contact-line recession lea-ving a macroscopic polymer film in the drying droplets of water-poly(N,N-dimethylacrylamide) solution[J]. Langmuir,2009,25(12):6934.
28 Kim J H, Park S B, Kim J H, et al. Polymer transports inside eva-porating water droplets at various substrate temperatures[J]. J Phys Chem C,2011,115:15375.
29 Hu Y C, et al. Various nucleation and surface profiles induced by micro-flows in drying droplets of water-poly(ethylene oxide) solution at heating substrates[J]. Petroleum Sci,2013,10(2):262.
30 Hu Y C, Zhou Q, Wang Y F, et al. Peculiar surface profile of poly(ethylene oxide) film with ring-like nucleation distribution induced by Marangoni flow effect[J]. Colloids Surf A,2013,428:39.
31 Kaya D, Belyi V A, et al. Pattern formation in drying droplets of polyelectrolyte and salt[J]. J Phys Chem,2010,133:114905-1.
32 Smalyukh I, Zribi O, Butler J, et al. Structure and dynamics of li-quid crystalline pattern formation in drying droplets of DNA[J]. Phys Rev Lett,2006,96: 177801-1.
33 Uno K, Hayashi K, Hayashi T, et al. Particle adsorption in evaporating droplets of polymer latex dispersions on hydrophilic and hydrophobic surfaces[J]. Colloid Polym Sci,1998,276(9):810.
34 Yakhno T A, et al. The informative-capacity phenomenon of drying drops[J]. IEEE Eng Medicine Biol Mag,2005,24(2): 96.
35 Yunker P J, Still T, et al. Suppression of the coffee-ring effect by shape-dependent capillary interactions[J]. Nature,2011,476:308.
36 Chris S H, Ding Y L, Simon B. The influence of nanoparticle shape on the drying of colloidal suspensions[J]. J Colloid Interface Sci,2010,352:99.
37 Sun P Z, Ma R Z, Wang K L, et al. Suppression of the coffee-ring effect by self-assembling graphene oxide and monolayer titania[J]. Nanotechnology,2013,24:075601-1.
38 Han W, Lin Z Q. Learning from “coffee rings”: Ordered structures enabled by controlled evaporative self-assembly[J]. Angew Chem Int Ed,2012, 51:1534.
39 Tekin E, Smith P J, Schubert U S. Inkjet printing as a deposition and patterning tool for polymers and inorganic particles[J]. Soft Matter,2008,4:703.
40 Wang L, Song Y. Controllable printing droplets for high-resolution patterns[J]. Adv Mater,2014,26:6950.
41 Kuang M, Wang J, Bao B, et al. Inkjet printing patterned photonic crystal domes for wide viewing-angle displays by controlling the sli-ding three phase contact Line[J]. Adv Opt Mater,2014,2:34.
42 Kyoohee W, et al. Ink-Jet printing of Cu-Ag based highly conductive tracks on a transparent substrate[J]. Langmuir,2009,25:429.
43 Yang Huixian,Su Caohui. Single dispersed Imagolite nanotubes from drying droplet[J]. Chin Sci Bull,2007,52(14):1719.
杨慧娴,苏朝晖.液滴蒸发形成单根分散的合成Imogolite纳米管[J].科学通报,2007,52(14):1719.
44 Shabalin V N, Shatokhina S N. Morphology of body liquids[M]. Moscow: Khrizostom,2001(in Russian).
45 Ajaev V S. Spreading of thin volatile liquid droplets on uniformly heated surfaces[J]. J Fluid Mech,2005,528:279.
46 Popov Y. Evaporative deposition patterns: Spatial dimensions of the deposit[J]. Phys Rev E,2005,71:36313.
47 Rabani E, Reichman D R, Geissler P L, et al. Drying-mediated self-assembly of nanoparticles[J]. Nature,2003,426:271.
48 Vancea I, Thiele U, et al. Front instabilities in evaporatively dewetting nanofluids[J]. Phys Rev E,2008,78:041601.
49 Khellil S. On the formation of regular patterns from drying droplets and their potential use for bio-medical applications[J]. J Bionic Eng,2010,7:S82.
50 Yakhno T A, Sedova O A, et al. On the existence of regular structures in liquid human blood serum (plasma) and phase transitions in the course of its drying[J]. Techn Phys,2003, 48: 399. |
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2017, Vol. 31 
