| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Recent Progress in Forces of Nanoscale Self-assembly |
| LAI Yuming, GAO Ya, YAO Xiuquan
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| National Center for Materials Service Safety, University of Science and Technology Beijing, Beijing 100083, China |
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Abstract Nanomaterials have excellent optical, mechanical and electrical properties, but many nanomaterials’ applications are not based on individual nano-objects but rather on ordered structures. Self-assembly is arguably the most efficient way for achieving organize nano-objects as it can make large numbers of individual particles into ordered structures. Ideal self-assembly is the process during which a collection of disorganized re-latively simple building block units combining into a minimal thermodynamic energy equilibrium ordered structure driven by the appropriate interaction force. If building block units were assembly in kinetics control process, it could lead to the formation of either precipitate or amorphous gels. Thus, the key of nanoscopic components assembly into lager structures is understanding the quantitative detail of interparticle interactions and manipulate it.
The results of competition between thermodynamic control and dynamic control are determined by the distance of interaction forces. The ideal driving force for self-assembly is the long-range force relative to the size of the building block units. Van der Waals force is a relatively short-range interaction force which acts appreciably over only molecular dimensions, could be utilized in smaller nanoscopic building block units which is most a few to tens of times larger than molecular length scales. Larger particles such as micrometer-scale colloids interacting through similar short-range attractive forces will invariably aggregate to form disordered precipitates or gels. In addition to the interaction length scale, the magnitude of the interaction forces can also affect the results of self-assembly system. Dynamically controlled disordered aggregates will be formed when the strength of interaction force in self-assembly system exceeds a certain range.
This review describes several interparticle forces including van der Waals force, electrostatic interaction, magnetic force, hydrogen bond, DNA base pair interaction, cross-linking interaction and molecular dipole interaction that can be used in nanoscale self-assembly. The magnitude and length scale of each type of interaction and the scaling with particle size and interparticle distance are discussed. The discussion emphasized on the unique characteristics to the nanoscale. When estimates the potential of interaction, limitations of theoretical simulations and examples of recent experimental systems are discussed.
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Published: 10 April 2020
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| Fund:This work was financially supported by the Fundamental Research Funds for the Central Universities (FRF-GF-18-003A). |
About author:: Yuming Laireceived her B.E. degree from Southwest University in 2008 and received her Ph.D. degree in physical chemistry from National Center for Nanoscience and Technology, Chinese Academy of Scien-ces, in 2014. She is an engineer in University of Scie-nce and Technology Beijing since 2014. Her research interests are surface/interface of materials and devices.
Ya Gaoreceived her B.S. degree in Composite Mate-rials and Engineering from Hebei University of Engineering in 2018. She is currently pursuing her master degree at National Center for Materials Service Safety, University of Science and Technology Beijing under the supervision of associate professor Lei Wen and doctor Yuming Lai. Her research focuses on corrosion inhibitors and their interaction with metals/alloys surfaces.
Xiuquan Yaoreceived his master’s degree in Mate-rials Science and Engineering from Inner Mongolia University of Science and Technology in 2018. He is currently pursuing his Ph.D. at the National Center for Materials Service Safety, University of Science and Technology Beijing under the supervision of Professor Ying Jin and Doctor Yuming Lai. His research focuses on corrosion inhibitors and their interaction with me-tals/alloys surfaces. |
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1 Zhang J L, Xue L J,Han Y C. Langmuir, 2005, 21, 5.
2 Cui Y, Lieber C M. Science, 2001, 291, 851.
3 Whitesides G M, Grzybowski B. Science, 2002, 295, 2418.
4 Fialkowski M, Bishop K J M, Klajn R,et al. Journal of Physical Chemistry B, 2006, 110, 2482.
5 Vericat C, Vela M E, Benitez G,et al. Chemical Society Reviews, 2010, 39, 1805.
6 Shevchenko E V, Talapin D V,Kotov N A,et al. Nature, 2006, 439, 55.
7 Klajn R, Bishop K J M, Fialkowski M,et al. Science, 2007, 316, 261.
8 Min Y J, Akbulut M, Kristiansen K,et al. Nature Materials, 2008, 7, 527.
9 Kulkarni S D, Walimbe P C, Ingulkar R B,et al. ACS Omega, 2019, 4, 13061.
10 Wei W, Zhang H, Wang W,et al. ACS Applied Materials & Interfaces, 2019, 11, 24478.
11 Marino E, Kodger T E, Wegdam G H,et al. Advanced Materials, 2018, 30, 1803433.
12 Bishop K J M, Wilmer C E, Soh S,et al. Small, 2009, 5, 1600.
13 Sau T K, Murphy C J. Langmuir, 2005, 21, 2923.
14 Mayer C R, Neveu S, Secheresse F,et al. Journal of Colloid and Interface Science, 2004, 273, 350.
15 Zhang H, Wang D. Angewandte Chemie-International Edition, 2008, 47, 3984.
16 Dawson K A. Current Opinion in Colloid & Interface Science, 2002, 7, 218.
17 Butter K, Bomans P H H, Frederik P M,et al. Nature Materials, 2003, 2, 88.
18 Chayen N E. Trends in Biotechnology, 2002, 20, 98.
19 Murray C B, Kagan C R, Bawendi M G. Annual Review of Materials Science, 2000, 30, 545.
20 Murray C B, Norris D J, Bawendi M G. Journal of the American Chemical Society, 1993, 115, 8706.
21 Yamaki M, Higo J, Nagayama K. Langmuir, 1995, 11, 2975.
22 Israelachvili J N. Intermolecular and surface forces, Academic Press,America, 2011.
23 Kalsin A M, Fialkowski M, Paszewski M,et al. Science, 2006, 312, 420.
24 Sepelak V, Baabe D, Mienert D,et al. Journal of Magnetism and Magnetic Materials, 2003, 257, 377.
25 Ahniyaz A, Sakamoto Y, Bergstrom L. Proceedings of the National Aca-demy of Sciences of the United States of America, 2007, 104, 17570.
26 Nonappa, Ikkala O. Advanced Functional Materials, 2018, 28, 14.
27 Thomas K G, Barazzouk S, Ipe B I,et al. Journal of Physical Chemistry B, 2004, 108, 13066.
28 Mirkin C A, Letsinger R L, Mucic R C,et al. Nature, 1996, 382, 607.
29 Pruneanu S, Al-Said S A F, Dong L Q,et al. Advanced Functional Materials, 2008, 18, 2444.
30 Yan H, Park S H, Finkelstein G,et al. Science, 2003, 301, 1882.
31 Sharma J, Chhabra R, Cheng A,et al. Science, 2009, 323, 112.
32 Puchner E M, Kufer S K, Strackharn M,et al. Nano Letters, 2008, 8, 3692.
33 Biancaniello P L, Kim A J, Crocker J C. Physical Review Letters, 2005, 94,058302-1.
34 Hinterwirth H, Kappel S, Waitz T,et al. ACS Nano, 2013, 7, 1129.
35 Wei Y H, Bishop K J M, Kim J,et al. Angewandte Chemie-International Edition, 2009, 48, 9477.
36 Klajn R, Bishop K J M, Grzybowski B A, Proceedings of the National Academy of Sciences of the United States of America, 2007, 107, 10305. |
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2020, Vol. 34 
