Interfacial induction and regulation for microscale crystallization process: a critical review

Mengyuan Wu , Zhijie Yuan , Yuchao Niu , Yingshuang Meng , Gaohong He , Xiaobin Jiang

Front. Chem. Sci. Eng. ›› 2022, Vol. 16 ›› Issue (6) : 838 -853.

PDF (2981KB)
Front. Chem. Sci. Eng. ›› 2022, Vol. 16 ›› Issue (6) : 838 -853. DOI: 10.1007/s11705-021-2129-8
REVIEW ARTICLE
REVIEW ARTICLE

Interfacial induction and regulation for microscale crystallization process: a critical review

Author information +
History +
PDF (2981KB)

Abstract

Microscale crystallization is at the frontier of chemical engineering, material science, and biochemical research and is affected by many factors. The precise regulation and control of microscale crystal processes is still a major challenge. In the heterogeneous induced nucleation process, the chemical and micro/nanostructural characteristics of the interface play a dominant role. Ideal crystal products can be obtained by modifying the interface characteristics, which has been proven to be a promising strategy. This review illustrates the application of interface properties, including chemical characteristics (hydrophobicity and functional groups) and the morphology of micro/nanostructures (rough structure and cavities, pore shape and pore size, surface porosity, channels), in various microscale crystallization controls and process intensification. Finally, possible future research and development directions are outlined to emphasize the importance of interfacial crystallization control and regulation for crystal engineering.

Graphical abstract

Keywords

interfacial crystallization / heterogeneous nucleation / supersaturation / micro/nanostructure / process control and intensification

Cite this article

Download citation ▾
Mengyuan Wu, Zhijie Yuan, Yuchao Niu, Yingshuang Meng, Gaohong He, Xiaobin Jiang. Interfacial induction and regulation for microscale crystallization process: a critical review. Front. Chem. Sci. Eng., 2022, 16(6): 838-853 DOI:10.1007/s11705-021-2129-8

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Shah U V, Amberg C, Diao Y, Yang Z, Heng J Y Y. Heterogeneous nucleants for crystallogenesis and bioseparation. Current Opinion in Chemical Engineering, 2015, 8: 69–75
[2]

Jiang X, Shao Y, Li J, Wu M, Niu Y, Ruan X, Yan X, Li X, He G. Bioinspired hybrid micro/nanostructure composited membrane with intensified mass transfer and antifouling for high saline water membrane distillation. ACS Nano, 2020, 14(12): 17376–17386
[3]

Bi Y, Cabriolu R, Li T. Heterogeneous ice nucleation controlled by the coupling of surface crystallinity and surface hydrophilicity. Journal of Physical Chemistry C, 2016, 120(3): 1507–1514
[4]

Wu Q, Gao A, Tao F, Yang P. Understanding biomolecular crystallization on amyloid-like superhydrophobic biointerface. Advanced Materials Interfaces, 2018, 5(6): 1701065
[5]

Liu Y X, Wang X J, Lu J, Ching C B. Influence of the roughness, topography, and physicochemical properties of chemically modified surfaces on the heterogeneous nucleation of protein crystals. Journal of Physical Chemistry B, 2007, 111(50): 13971–13978
[6]

Curcio E, Curcio V, Profio G D, Fontananova E, Drioli E. Energetics of protein nucleation on rough polymeric surfaces. Journal of Physical Chemistry B, 2010, 114(43): 13650–13655
[7]

Paxton T E, Sambanis A, Rousseau R W. Influence of vessel surfaces on the nucleation of protein crystals. Langmuir, 2001, 17(10): 3076–3079
[8]

Wang M, Liu G, Yu H, Lee S H, Wang L, Zheng J, Wang T, Yun Y, Lee J K. ZnO nanorod array modified PVDF membrane with superhydrophobic surface for vacuum membrane distillation application. ACS Applied Materials & Interfaces, 2018, 10(16): 13452–13461
[9]

Jiang X, Tuo L, Lu D, Hou B, Chen W, He G. Progress in membrane distillation crystallization: process models, crystallization control and innovative applications. Frontiers of Chemical Science and Engineering, 2017, 11(4): 647–662
[10]

Leaper S, Abdel-Karim A, Gorgojo P. The use of carbon nanomaterials in membrane distillation membranes: a review. Frontiers of Chemical Science and Engineering, 2021, 15(4): 755–774
[11]

Rehman W U, Muhammad A, Younas M, Wu C, Hu Y, Li J. Effect of membrane wetting on the performance of PVDF and PTFE membranes in the concentration of pomegranate juice through osmotic distillation. Journal of Membrane Science, 2019, 584: 66–78
[12]

Liu C, Chen L, Zhu L. Fouling mechanism of hydrophobic polytetrafluoroethylene (PTFE) membrane by differently charged organics during direct contact membrane distillation (DCMD) process: an especial interest in the feed properties. Journal of Membrane Science, 2018, 548: 125–135
[13]

Saffarini R B, Mansoor B, Thomas R, Arafat H A. Effect of temperature-dependent microstructure evolution on pore wetting in PTFE membranes under membrane distillation conditions. Journal of Membrane Science, 2013, 429: 282–294
[14]

Shao Y, Han M, Wang Y, Li G, Xiao W, Li X, Wu X, Ruan X, Yan X, He G, Jiang X. Superhydrophobic polypropylene membrane with fabricated antifouling interface for vacuum membrane distillation treating high concentration sodium/magnesium saline water. Journal of Membrane Science, 2019, 579: 240–252
[15]

Wang Y, He G, Shao Y, Zhang D, Ruan X, Xiao W, Li X, Wu X, Jiang X. Enhanced performance of superhydrophobic polypropylene membrane with modified antifouling surface for high salinity water treatment. Separation and Purification Technology, 2019, 214: 11–20
[16]

Lv J, Song Y, Jiang L, Wang J. Bio-inspired strategies for anti-icing. ACS Nano, 2014, 8(4): 3152–3169
[17]

Eberle P, Tiwari M K, Maitra T, Poulikakos D. Rational nanostructuring of surfaces for extraordinary icephobicity. Nanoscale, 2014, 6(9): 4874–4881
[18]

Zhang Z, Liu X Y. Control of ice nucleation: freezing and antifreeze strategies. Chemical Society Reviews, 2018, 47(18): 7116–7139
[19]

Tang Y, Zhang Q, Zhan X, Chen F. Superhydrophobic and anti-icing properties at overcooled temperature of a fluorinated hybrid surface prepared via a sol-gel process. Soft Matter, 2015, 11(22): 4540–4550
[20]

Meuler A J, Mckinley G H, Cohen R E. Exploiting topographical texture to impart icephobicity. ACS Nano, 2010, 4(12): 7048–7052
[21]

Nanev C N, Saridakis E, Govada L, Kassen S C, Solomon H V, Chayen N E. Hydrophobic interface-assisted protein crystallization: theory and experiment. ACS Applied Materials & Interfaces, 2019, 11(13): 12931–12940
[22]

Nanev C. Protein crystal nucleation: recent notions. Crystal Research and Technology, 2007, 42(1): 4–12
[23]

Nanev C. Recent insights into protein crystal nucleation. Crystals, 2018, 8(219): 1–12
[24]

Nanev C. Peculiarities of protein crystal nucleation and growth. Crystals, 2018, 8(422): 1–16
[25]

Pham T, Lai D, Ji D, Tuntiwechapikul W, Friedman J M, Lee T R. Well-ordered self-assembled monolayer surfaces can be used to enhance the growth of protein crystals. Colloids and Surfaces. B, Biointerfaces, 2004, 34(3): 191–196
[26]

D’Arcy A, Sweeney A M, Haber A. Using natural seeding material to generate nucleation in protein crystallization experiments. Acta Crystallographica. Section D, Biological Crystallography, 2003, D59(7): 1343–1346
[27]

Boinovich L B, Emelyanenko A M. Hydrophobic materials and coatings: principles of design, properties and applications. Russian Chemical Reviews, 2008, 77(7): 583–600
[28]

Brassard J D, Sarkar D K, Perron J. Fluorine based superhydrophobic coatings. Applied Sciences (Basel, Switzerland), 2012, 2(2): 453–464
[29]

Li L, Li B, Dong J, Zhang J. Roles of silanes and silicones in forming superhydrophobic and superoleophobic materials. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2016, 4(36): 13677–13725
[30]

Xiao Z, Zheng R, Liu Y, He H, Yuan X, Ji Y, Li D, Yin H, Zhang Y, Li X M, He T. Slippery for scaling resistance in membrane distillation: a novel porous micropillared superhydrophobic surface. Water Research, 2019, 155: 152–161
[31]

Song Y Y, Felix S S, Bauer S, Schmuki P. Amphiphilic TiO2 nanotube arrays: an actively controllable drug delivery system. Journal of the American Chemical Society, 2009, 131(12): 4230–4232
[32]

Fan X, Su Y, Zhao X, Li Y, Zhang R, Ma T, Liu Y, Jiang Z. Manipulating the segregation behavior of polyethylene glycol by hydrogen bonding interaction to endow ultrafiltration membranes with enhanced antifouling performance. Journal of Membrane Science, 2016, 499: 56–64
[33]

Chang Y, Ko C Y, Shih Y J, Quémener D, Deratani A, Wei T C, Wang D M, Lai J Y. Surface grafting control of PEGylated poly(vinylidene fluoride) antifouling membrane via surface-initiated radical graft copolymerization. Journal of Membrane Science, 2009, 345(1-2): 160–169
[34]

Chen L H, Huang A, Chen Y R, Chen C H, Hsu C C, Tsai F Y, Tung K L. Omniphobic membranes for direct contact membrane distillation: effective deposition of zinc oxide nanoparticles. Desalination, 2018, 428: 255–263
[35]

Dong Y, Ma L, Tang C Y, Yang F, Quan X, Jassby D, Zaworotko M J, Guiver M D. Stable superhydrophobic ceramic-based carbon nanotube composite desalination membranes. Nano Letters, 2018, 18(9): 5514–5521
[36]

Liu Y, Su Y, Cao J, Guan J, Zhang R, He M, Fan L, Zhang Q, Jiang Z. Antifouling, high-flux oil/water separation carbon nanotube membranes by polymer-mediated surface charging and hydrophilization. Journal of Membrane Science, 2017, 542: 254–263
[37]

Dixit D, Ghoroi C. Role of randomly distributed nanoscale roughness for designing highly hydrophobic particle surface without using low surface energy coating. Journal of Colloid and Interface Science, 2020, 564: 8–18
[38]

Mohammadi E, Qu G, Kafle P, Jung S H, Lee J K, Diao Y. Design rules for dynamic-template-directed crystallization of conjugated polymers. Molecular Systems Design & Engineering, 2020, 5(1): 125–138
[39]

Curcio E, López-Mejías V, Di Profio G, Fontananova E, Drioli E, Trout B L, Myerson A S. Regulating nucleation kinetics through molecular interactions at the polymer-solute interface. Crystal Growth & Design, 2014, 14(2): 678–686
[40]

Wang Z, Dong X, Liu G, Xing Q, Cavallo D, Jiang Q, Müller A J, Wang D. Interfacial nucleation in iPP/PB-1 blends promotes the formation of polybutene-1 trigonal crystals. Polymer, 2018, 138: 396–406
[41]

Flieger A K, Schulz M, Thurn-Albrecht T. Interface-induced crystallization of polycaprolactone on graphite via first-order prewetting of the crystalline phase. Macromolecules, 2017, 51(1): 189–194
[42]

Kim H, Hong J, Kim C, Shin E Y, Lee M J, Noh Y Y, Park B C, Hwang I. Impact of hydroxyl groups boosting heterogeneous nucleation on perovskite grains and photovoltaic performances. Journal of Physical Chemistry C, 2018, 122(29): 16630–16638
[43]

López-Mejías V, Myerson A S, Trout B L. Geometric design of heterogeneous nucleation sites on biocompatible surfaces. Crystal Growth & Design, 2013, 13(8): 3835–3841
[44]

Macedonio F, Politano A, Drioli E, Gugliuzza A. Bi2Se3-assisted membrane crystallization. Materials Horizons, 2018, 5(5): 912–919
[45]

Suzuki H, Takiyama H. Observation and evaluation of crystal growth phenomena of glycine at the template interface with L-leucine. Advanced Powder Technology, 2016, 27(5): 2161–2167
[46]

Tsekova D S, Williams D R, Heng J Y Y. Effect of surface chemistry of novel templates on crystallization of proteins. Chemical Engineering Science, 2012, 77: 201–206
[47]

Diao Y, Harada T, Myerson A S, Hatton T A, Trout B L. The role of nanopore shape in surface-induced crystallization. Nature Materials, 2011, 10(11): 867–871
[48]

Diao Y, Helgeson M E, Siam Z A, Doyle P S, Myerson A S, Hatton T A, Trout B L. Nucleation under soft confinement: role of polymer-solute interactions. Crystal Growth & Design, 2011, 12(1): 508–517
[49]

Diao Y, Myerson A S, Hatton T A, Trout B L. Surface design for controlled crystallization: the role of surface chemistry and nanoscale pores in heterogeneous nucleation. Langmuir, 2011, 27(9): 5324–5334
[50]

Luo S, Kui X, Xing E, Wang X, Xue G, Schick C, Hu W, Zhuravlev E, Zhou D. Interplay between free surface and solid interface nucleation on two-step crystallization of poly(ethylene terephthalate) thin films studied by fast scanning calorimetry. Macromolecules, 2018, 51(14): 5209–5218
[51]

Grosfils P, Lutsko J F. Impact of surface roughness on crystal nucleation. Crystals, 2020, 11(4): 1–20
[52]

Abyzov A S, Schmeizer J W P, Davydov L N. Heterogeneous nucleation on rough surfaces: generalized Gibbs’ approach. Journal of Chemical Physics, 2017, 147(21): 214705
[53]

Yan D, Zeng Q, Xu S, Zhang Q, Wang J. Heterogeneous nucleation on concave rough surfaces: thermodynamic analysis and implications for nucleation design. Journal of Physical Chemistry C, 2016, 120(19): 10368–10380
[54]

Su B, Tian Y, Jiang L. Bioinspired interfaces with superwettability: from materials to chemistry. Journal of the American Chemical Society, 2016, 138(6): 1727–1748
[55]

Liu K, Cao M, Fujishima A, Jiang L. Bio-inspired titanium dioxide materials with special wettability and their applications. Chemical Reviews, 2014, 114(19): 10044–10094
[56]

Karthika S, Radhakrishnan T K, Kalaichelvi P. A review of classical and nonclassical nucleation theories. Crystal Growth & Design, 2016, 16(11): 6663–6681
[57]

Salehi S M, Manjua A C, Belviso B D, Portugal C A M, Coelhoso I M, Mirabelli V, Fontananova E, Caliandro R, Crespo J G, Curcio E, . Hydrogel composite membranes incorporating iron oxide nanoparticles as topographical designers for controlled heteronucleation of proteins. Crystal Growth & Design, 2018, 18(6): 3317–3327
[58]

Cao L, Price T P, Weiss M, Gao D. Super water- and oil-repellent surfaces on intrinsically hydrophilic and oleophilic porous silicon films. Langmuir, 2008, 24(5): 1640–1643
[59]

Nosonovsky M. Multiscale roughness and stability of superhydrophobic biomimetic interfaces. Langmuir, 2007, 23(6): 3157–3161
[60]

Nanev C N, Saridakis E, Chayen N E. Protein crystal nucleation in pores. Scientific Reports, 2017, 7(1): 35821
[61]

Pach E, Verdaguer A. Pores dominate ice nucleation on feldspars. Journal of Physical Chemistry C, 2019, 123(34): 20998–21004
[62]

Wei P S, Hsiao S Y. Effects of supersaturation on pore shape in solid. Journal of Crystal Growth, 2017, 460: 126–133
[63]

Chayen N E, Saridakis E, Sear R P. Experiment and theory for heterogeneous nucleation of protein crystals in a porous medium. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103(3): 597–601
[64]

Shah U V, Williams D R, Heng J Y Y. Selective crystallization of proteins using engineered nanonucleants. Crystal Growth & Design, 2012, 12(3): 1362–1369
[65]

Lu D, Liu Z, Wu J. Structural transitions of confined model proteins: molecular dynamics simulation and experimental validation. Biophysical Journal, 2006, 90(9): 3224–3238
[66]

Diao Y, Helgeson M E, Myerson A S, Hatton T A, Doyle P S, Trout B L. Controlled nucleation from solution using polymer microgels. Journal of the American Chemical Society, 2011, 133(11): 3756–3759
[67]

Stojaković J, Baftizadeh F, Bellucci M A, Myerson A S, Trout B L. Angle-directed nucleation of paracetamol on biocompatible nanoimprinted polymers. Crystal Growth & Design, 2017, 17(6): 2955–2963
[68]

Asanithi P. Surface porosity and roughness of micrographite film for nucleation of hydroxyapatite. Journal of Biomedical Materials Research. Part A, 2014, 102(8): 2590–2599
[69]

Frenkel D. Seeds of phase change. Nature, 2006, 443(7112): 641
[70]

Meng S, Ye Y, Mansouri J, Chen V. Fouling and crystallisation behaviour of superhydrophobic nano-composite PVDF membranes in direct contact membrane distillation. Journal of Membrane Science, 2014, 463: 102–112
[71]

Nindiyasari F, Fernández-Díaz L, Griesshaber E, Astilleros J M, Sánchez-Pastor N, Schmahl W W. Influence of gelatin hydrogel porosity on the crystallization of CaCO3. Crystal Growth & Design, 2014, 14(4): 1531–1542
[72]

Jo M K, Oh Y, Kim H J, Kim H L, Yang S H. Diffusion-controlled crystallization of calcium carbonate in a hydrogel. Crystal Growth & Design, 2019, 20(2): 560–567
[73]

Jiang X, Lu D, Xiao W, Ruan X, Fang J, He G. Membrane assisted cooling crystallization: process model, nucleation, metastable zone, and crystal size distribution. AIChE Journal. American Institute of Chemical Engineers, 2016, 62(3): 829–841
[74]

Cui Z, Li X, Zhang Y, Wang Z, Gugliuzza A, Militano F, Drioli E, Macedonio F. Testing of three different PVDF membranes in membrane assisted-crystallization process: influence of membrane structural-properties on process performance. Desalination, 2018, 440: 68–77
[75]

Ko C C, Ali A, Drioli E, Tung K L, Chen C H, Chen Y R, Macedonio F. Performance of ceramic membrane in vacuum membrane distillation and in vacuum membrane crystallization. Desalination, 2018, 440: 48–58
[76]

Hong X, Huang X J, Gao Q L, Wu H M, Guo Y Z, Huang F, Fang F, Huang H T, Chen D J. Microstructure-performance relationships of hollow-fiber membranes with highly efficient separation of oil-in-water emulsions. Journal of Applied Polymer Science, 2019, 136(23): 47615
[77]

Gao S, Shi Z, Zhang W B, Zhang F, Jin J. Photo-induced superwetting single-walled carbon nanotube/TiO2 ultrathin network films for ultrafast separation of oil-in-water emulsions. ACS Nano, 2014, 8(6): 6344–6352
[78]

Fang A, Hailey A K, Grosskopf A, Anthony J E, Loo Y L, Haataj M. Capillary effects in guided crystallization of organic thin films. APL Materials, 2015, 3(036107): 036107
[79]

Ahmad F, Rahimi A, Tsotsas E, Prat M, Kharaghani A. From micro-scale to macro-scale modeling of solute transport in drying capillary porous media. International Journal of Heat and Mass Transfer, 2021, 165: 120722
[80]

Mandiang Y, Sene M, Thiam A, Azillinon D. Daily estimate of pure water in a desalination unit by solar membrane distillation. Journal of Marine Science and Engineering, 2015, 4(3): 1–7
[81]

Cai J, Perfect E, Cheng C L, Hu X. Generalized modeling of spontaneous imbibition based on Hagen-Poiseuille flow in tortuous capillaries with variably shaped apertures. Langmuir, 2014, 30(18): 5142–5151
[82]

Vincent O, Zhang J, Choi E, Zhu S, Stroock A D. How solutes modify the thermodynamics and dynamics of filling and emptying in extreme ink-bottle pores. Langmuir, 2019, 35(8): 2934–2947
[83]

Desgranges C, Delhommelle J. Nucleation of capillary bridges and bubbles in nanoconfined CO2. Langmuir, 2019, 35(47): 15401–15409
[84]

Shah U V, Allenby M C, Williams D R, Heng J Y Y. Crystallization of proteins at ultralow supersaturations using novel three-dimensional nanotemplates. Crystal Growth & Design, 2012, 12(4): 1772–1777
[85]

Jensen K F. Flow chemistry—microreaction technology comes of age. AIChE Journal. American Institute of Chemical Engineers, 2017, 63(3): 858–869
[86]

Koizumi H, Fujiwara K, Uda S. Role of the electric double layer in controlling the nucleation rate for tetragonal hen egg white lysozyme crystals by application of an external electric field. Crystal Growth & Design, 2010, 10(6): 2591–2595
[87]

Bhangu S K, Ashokkumar M, Lee J. Ultrasound assisted crystallization of paracetamol: crystal size distribution and polymorph control. Crystal Growth & Design, 2016, 16(4): 1934–1941
[88]

Tuo L, Ruan X, Xiao W, Li X, He G, Jiang X. A novel hollow fiber membrane-assisted antisolvent crystallization for enhanced mass transfer process control. AIChE Journal. American Institute of Chemical Engineers, 2019, 65(2): 734–744

RIGHTS & PERMISSIONS

Higher Education Press

AI Summary AI Mindmap
PDF (2981KB)

6817

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/