fbpx
Wikipedia

Self-assembly

February 16, 2024

For other uses, see Self-construction (disambiguation).

Self-assembly is a process in which a disordered system of pre-existing components forms an organized structure or pattern as a consequence of specific, local interactions among the components themselves, without external direction. When the constitutive components are molecules, the process is termed molecular self-assembly.

Self-assembly of lipids (a), proteins (b), and (c) SDS-cyclodextrin complexes. SDS is a surfactant with a hydrocarbon tail (yellow) and a SO4 head (blue and red), while cyclodextrin is a saccharide ring (green C and red O atoms).
Transmission electron microscopy image of an iron oxide nanoparticle. Regularly arranged dots within the dashed border are columns of Fe atoms. Left inset is the corresponding electron diffraction pattern. Scale bar: 10 nm.[1]
Iron oxide nanoparticles can be dispersed in an organic solvent (toluene). Upon its evaporation, they may self-assemble (left and right panels) into micron-sized mesocrystals (center) or multilayers (right). Each dot in the left image is a traditional "atomic" crystal shown in the image above. Scale bars: 100 nm (left), 25 μm (center), 50 nm (right).[1]
STM image of self-assembled Br4-pyrene molecules on Au(111) surface (top) and its model (bottom; pink spheres are Br atoms).[2]
AFM imaging of self-assembly of 2-aminoterephthalic acid molecules on (104)-oriented calcite.[3]

Self-assembly can be classified as either static or dynamic. In static self-assembly, the ordered state forms as a system approaches equilibrium, reducing its free energy. However, in dynamic self-assembly, patterns of pre-existing components organized by specific local interactions are not commonly described as "self-assembled" by scientists in the associated disciplines. These structures are better described as "self-organized", although these terms are often used interchangeably.

In chemistry and materials science edit

 
The DNA structure at left (schematic shown) will self-assemble into the structure visualized by atomic force microscopy at right.

Self-assembly in the classic sense can be defined as the spontaneous and reversible organization of molecular units into ordered structures by non-covalent interactions. The first property of a self-assembled system that this definition suggests is the spontaneity of the self-assembly process: the interactions responsible for the formation of the self-assembled system act on a strictly local level—in other words, the nanostructure builds itself.

Although self-assembly typically occurs between weakly-interacting species, this organization may be transferred into strongly-bound covalent systems. An example for this may be observed in the self-assembly of polyoxometalates. Evidence suggests that such molecules assemble via a dense-phase type mechanism whereby small oxometalate ions first assemble non-covalently in solution, followed by a condensation reaction that covalently binds the assembled units.[4] This process can be aided by the introduction of templating agents to control the formed species.[5] In such a way, highly organized covalent molecules may be formed in a specific manner.

Self-assembled nano-structure is an object that appears as a result of ordering and aggregation of individual nano-scale objects guided by some physical principle.

A particularly counter-intuitive example of a physical principle that can drive self-assembly is entropy maximization. Though entropy is conventionally associated with disorder, under suitable conditions [6] entropy can drive nano-scale objects to self-assemble into target structures in a controllable way.[7]

Another important class of self-assembly is field-directed assembly. An example of this is the phenomenon of electrostatic trapping. In this case an electric field is applied between two metallic nano-electrodes. The particles present in the environment are polarized by the applied electric field. Because of dipole interaction with the electric field gradient the particles are attracted to the gap between the electrodes.[8] Generalizations of this type approach involving different types of fields, e.g., using magnetic fields, using capillary interactions for particles trapped at interfaces, elastic interactions for particles suspended in liquid crystals have also been reported.

Regardless of the mechanism driving self-assembly, people take self-assembly approaches to materials synthesis to avoid the problem of having to construct materials one building block at a time. Avoiding one-at-a-time approaches is important because the amount of time required to place building blocks into a target structure is prohibitively difficult for structures that have macroscopic size.

Once materials of macroscopic size can be self-assembled, those materials can find use in many applications. For example, nano-structures such as nano-vacuum gaps are used for storing energy[9] and nuclear energy conversion.[10] Self-assembled tunable materials are promising candidates for large surface area electrodes in batteries and organic photovoltaic cells, as well as for microfluidic sensors and filters.[11]

Distinctive features edit

At this point, one may argue that any chemical reaction driving atoms and molecules to assemble into larger structures, such as precipitation, could fall into the category of self-assembly. However, there are at least three distinctive features that make self-assembly a distinct concept.

Order edit

First, the self-assembled structure must have a higher order than the isolated components, be it a shape or a particular task that the self-assembled entity may perform. This is generally not true in chemical reactions, where an ordered state may proceed towards a disordered state depending on thermodynamic parameters.

Interactions edit

The second important aspect of self-assembly is the predominant role of weak interactions (e.g. Van der Waals, capillary,  , hydrogen bonds, or entropic forces) compared to more "traditional" covalent, ionic, or metallic bonds. These weak interactions are important in materials synthesis for two reasons.

First, weak interactions take a prominent place in materials, especially in biological systems. For instance, they determine the physical properties of liquids, the solubility of solids, and the organization of molecules in biological membranes.[12]

Second, in addition to the strength of the interactions, interactions with varying degrees of specificity can control self-assembly. Self-assembly that is mediated by DNA pairing interactions constitutes the interactions of the highest specificity that have been used to drive self-assembly.[13] At the other extreme, the least specific interactions are possibly those provided by emergent forces that arise from entropy maximization.[6]

Building blocks edit

The third distinctive feature of self-assembly is that the building blocks are not only atoms and molecules, but span a wide range of nano- and mesoscopic structures, with different chemical compositions, functionalities,[14] and shapes.[15] Research into possible three-dimensional shapes of self-assembling micrites examines Platonic solids (regular polyhedral). The term 'micrite' was created by DARPA to refer to sub-millimeter sized microrobots, whose self-organizing abilities may be compared with those of slime mold.[16][17] Recent examples of novel building blocks include polyhedra and patchy particles.[14] Examples also included microparticles with complex geometries, such as hemispherical,[18] dimer,[19] discs,[20] rods, molecules, as well as multimers. These nanoscale building blocks can in turn be synthesized through conventional chemical routes or by other self-assembly strategies such as directional entropic forces. More recently, inverse design approaches have appeared where it is possible to fix a target self-assembled behavior, and determine an appropriate building block that will realize that behavior.[7]

Thermodynamics and kinetics edit

Self-assembly in microscopic systems usually starts from diffusion, followed by the nucleation of seeds, subsequent growth of the seeds, and ends at Ostwald ripening. The thermodynamic driving free energy can be either enthalpic or entropic or both.[6] In either the enthalpic or entropic case, self-assembly proceeds through the formation and breaking of bonds,[21] possibly with non-traditional forms of mediation. The kinetics of the self-assembly process is usually related to diffusion, for which the absorption/adsorption rate often follows a Langmuir adsorption model which in the diffusion controlled concentration (relatively diluted solution) can be estimated by the Fick's laws of diffusion. The desorption rate is determined by the bond strength of the surface molecules/atoms with a thermal activation energy barrier. The growth rate is the competition between these two processes.

Examples edit

Important examples of self-assembly in materials science include the formation of molecular crystals, colloids, lipid bilayers, phase-separated polymers, and self-assembled monolayers.[22][23] The folding of polypeptide chains into proteins and the folding of nucleic acids into their functional forms are examples of self-assembled biological structures. Recently, the three-dimensional macroporous structure was prepared via self-assembly of diphenylalanine derivative under cryoconditions, the obtained material can find the application in the field of regenerative medicine or drug delivery system.[24] P. Chen et al. demonstrated a microscale self-assembly method using the air-liquid interface established by Faraday wave as a template. This self-assembly method can be used for generation of diverse sets of symmetrical and periodic patterns from microscale materials such as hydrogels, cells, and cell spheroids.[25] Yasuga et al. demonstrated how fluid interfacial energy drives the emergence of three-dimensional periodic structures in micropillar scaffolds.[26] Myllymäki et al. demonstrated the formation of micelles, that undergo a change in morphology to fibers and eventually to spheres, all controlled by solvent change.[27]

Properties edit

Self-assembly extends the scope of chemistry aiming at synthesizing products with order and functionality properties, extending chemical bonds to weak interactions and encompassing the self-assembly of nanoscale building blocks at all length scales.[28] In covalent synthesis and polymerization, the scientist links atoms together in any desired conformation, which does not necessarily have to be the energetically most favoured position; self-assembling molecules, on the other hand, adopt a structure at the thermodynamic minimum, finding the best combination of interactions between subunits but not forming covalent bonds between them. In self-assembling structures, the scientist must predict this minimum, not merely place the atoms in the location desired.

Another characteristic common to nearly all self-assembled systems is their thermodynamic stability. For self-assembly to take place without intervention of external forces, the process must lead to a lower Gibbs free energy, thus self-assembled structures are thermodynamically more stable than the single, unassembled components. A direct consequence is the general tendency of self-assembled structures to be relatively free of defects. An example is the formation of two-dimensional superlattices composed of an orderly arrangement of micrometre-sized polymethylmethacrylate (PMMA) spheres, starting from a solution containing the microspheres, in which the solvent is allowed to evaporate slowly in suitable conditions. In this case, the driving force is capillary interaction, which originates from the deformation of the surface of a liquid caused by the presence of floating or submerged particles.[29]

These two properties—weak interactions and thermodynamic stability—can be recalled to rationalise another property often found in self-assembled systems: the sensitivity to perturbations exerted by the external environment. These are small fluctuations that alter thermodynamic variables that might lead to marked changes in the structure and even compromise it, either during or after self-assembly. The weak nature of interactions is responsible for the flexibility of the architecture and allows for rearrangements of the structure in the direction determined by thermodynamics. If fluctuations bring the thermodynamic variables back to the starting condition, the structure is likely to go back to its initial configuration. This leads us to identify one more property of self-assembly, which is generally not observed in materials synthesized by other techniques: reversibility.

Self-assembly is a process which is easily influenced by external parameters. This feature can make synthesis rather complex because of the need to control many free parameters. Yet self-assembly has the advantage that a large variety of shapes and functions on many length scales can be obtained.[30]

The fundamental condition needed for nanoscale building blocks to self-assemble into an ordered structure is the simultaneous presence of long-range repulsive and short-range attractive forces.[31]

By choosing precursors with suitable physicochemical properties, it is possible to exert a fine control on the formation processes that produce complex structures. Clearly, the most important tool when it comes to designing a synthesis strategy for a material, is the knowledge of the chemistry of the building units. For example, it was demonstrated that it was possible to use diblock copolymers with different block reactivities in order to selectively embed maghemite nanoparticles and generate periodic materials with potential use as waveguides.[32]

In 2008 it was proposed that every self-assembly process presents a co-assembly, which makes the former term a misnomer. This thesis is built on the concept of mutual ordering of the self-assembling system and its environment.[33]

At the macroscopic scale edit

The most common examples of self-assembly at the macroscopic scale can be seen at interfaces between gases and liquids, where molecules can be confined at the nanoscale in the vertical direction and spread over long distances laterally. Examples of self-assembly at gas-liquid interfaces include breath-figures, self-assembled monolayers, droplet clusters, and Langmuir–Blodgett films, while crystallization of fullerene whiskers is an example of macroscopic self-assembly in between two liquids.[34][35] Another remarkable example of macroscopic self-assembly is the formation of thin quasicrystals at an air-liquid interface, which can be built up not only by inorganic, but also by organic molecular units.[36][37] Furthermore, it was reported that Fmoc protected L-DOPA amino acid (Fmoc-DOPA)[38][39] can present a minimal supramolecular polymer model, displaying a spontaneous structural transition from meta-stable spheres to fibrillar assemblies to gel-like material and finally to single crystals.[40]

Self-assembly processes can also be observed in systems of macroscopic building blocks. These building blocks can be externally propelled[41] or self-propelled.[42] Since the 1950s, scientists have built self-assembly systems exhibiting centimeter-sized components ranging from passive mechanical parts to mobile robots.[43] For systems at this scale, the component design can be precisely controlled. For some systems, the components' interaction preferences are programmable. The self-assembly processes can be easily monitored and analyzed by the components themselves or by external observers.[44]

In April 2014, a 3D printed plastic was combined with a "smart material" that self-assembles in water,[45] resulting in "4D printing".[46]

Consistent concepts of self-organization and self-assembly edit

People regularly use the terms "self-organization" and "self-assembly" interchangeably. As complex system science becomes more popular though, there is a higher need to clearly distinguish the differences between the two mechanisms to understand their significance in physical and biological systems. Both processes explain how collective order develops from "dynamic small-scale interactions".[47] Self-organization is a non-equilibrium process where self-assembly is a spontaneous process that leads toward equilibrium. Self-assembly requires components to remain essentially unchanged throughout the process. Besides the thermodynamic difference between the two, there is also a difference in formation. The first difference is what "encodes the global order of the whole" in self-assembly whereas in self-organization this initial encoding is not necessary. Another slight contrast refers to the minimum number of units needed to make an order. Self-organization appears to have a minimum number of units whereas self-assembly does not. The concepts may have particular application in connection with natural selection.[48] Eventually, these patterns may form one theory of pattern formation in nature.[49]

See also edit

References edit

  1. ^ a b Wetterskog E, Agthe M, Mayence A, Grins J, Wang D, Rana S, et al. (October 2014). "Precise control over shape and size of iron oxide nanocrystals suitable for assembly into ordered particle arrays". Science and Technology of Advanced Materials. 15 (5): 055010. Bibcode:2014STAdM..15e5010W. doi:10.1088/1468-6996/15/5/055010. PMC 5099683. PMID 27877722.
  2. ^ Pham TA, Song F, Nguyen MT, Stöhr M (November 2014). "Self-assembly of pyrene derivatives on Au(111): substituent effects on intermolecular interactions". Chemical Communications. 50 (91): 14089–92. doi:10.1039/C4CC02753A. PMID 24905327.
  3. ^ Kling F (2016). Diffusion and structure formation of molecules on calcite(104) (PhD). Johannes Gutenberg University Mainz. doi:10.25358/openscience-2179.
  4. ^ Schreiber RE, Avram L, Neumann R (January 2018). "Self-Assembly through Noncovalent Preorganization of Reactants: Explaining the Formation of a Polyfluoroxometalate". Chemistry: A European Journal. 24 (2): 369–379. doi:10.1002/chem.201704287. PMID 29064591.
  5. ^ Miras HN, Cooper GJ, Long DL, Bögge H, Müller A, Streb C, Cronin L (January 2010). "Unveiling the transient template in the self-assembly of a molecular oxide nanowheel". Science. 327 (5961): 72–4. Bibcode:2010Sci...327...72M. doi:10.1126/science.1181735. PMID 20044572. S2CID 24736211.
  6. ^ a b c van Anders G, Klotsa D, Ahmed NK, Engel M, Glotzer SC (November 2014). "Understanding shape entropy through local dense packing". Proceedings of the National Academy of Sciences of the United States of America. 111 (45): E4812-21. arXiv:1309.1187. Bibcode:2014PNAS..111E4812V. doi:10.1073/pnas.1418159111. PMC 4234574. PMID 25344532.
  7. ^ a b Geng Y, van Anders G, Dodd PM, Dshemuchadse J, Glotzer SC (July 2019). "Engineering entropy for the inverse design of colloidal crystals from hard shapes". Science Advances. 5 (7): eaaw0514. arXiv:1712.02471. Bibcode:2019SciA....5..514G. doi:10.1126/sciadv.aaw0514. PMC 6611692. PMID 31281885.
  8. ^ Bezryadin A, Westervelt RM, Tinkham M (1999). "Self-assembled chains of graphitized carbon nanoparticles". Applied Physics Letters. 74 (18): 2699–2701. arXiv:cond-mat/9810235. Bibcode:1999ApPhL..74.2699B. doi:10.1063/1.123941. S2CID 14398155.
  9. ^ Lyon D, Hubler A (2013). "Gap size dependence of the dielectric strength in nano vacuum gaps". IEEE Transactions on Dielectrics and Electrical Insulation. 20 (4): 1467–1471. doi:10.1109/TDEI.2013.6571470. S2CID 709782.
  10. ^ Shinn E (2012). "Nuclear energy conversion with stacks of graphene nanocapacitors". Complexity. 18 (3): 24–27. Bibcode:2013Cmplx..18c..24S. doi:10.1002/cplx.21427.
  11. ^ Demortière A, Snezhko A, Sapozhnikov MV, Becker N, Proslier T, Aranson IS (2014). "Self-assembled tunable networks of sticky colloidal particles". Nature Communications. 5: 3117. Bibcode:2014NatCo...5.3117D. doi:10.1038/ncomms4117. PMID 24445324.
  12. ^ Israelachvili JN (2011). Intermolecular and Surface Forces (3rd ed.). Elsevier.
  13. ^ Jones MR, Seeman NC, Mirkin CA (February 2015). "Nanomaterials. Programmable materials and the nature of the DNA bond". Science. 347 (6224): 1260901. doi:10.1126/science.1260901. PMID 25700524.
  14. ^ a b Glotzer SC, Solomon MJ (August 2007). "Anisotropy of building blocks and their assembly into complex structures". Nature Materials. 6 (8): 557–62. doi:10.1038/nmat1949. PMID 17667968.
  15. ^ van Anders G, Ahmed NK, Smith R, Engel M, Glotzer SC (January 2014). "Entropically patchy particles: engineering valence through shape entropy". ACS Nano. 8 (1): 931–40. arXiv:1304.7545. doi:10.1021/nn4057353. PMID 24359081. S2CID 9669569.
  16. ^ Solem JC (2002). "Self-assembling micrites based on the Platonic solids". Robotics and Autonomous Systems. 38 (2): 69–92. doi:10.1016/s0921-8890(01)00167-1.
  17. ^ Trewhella J, Solem JC (1998). "Future Research Directions for Los Alamos: A Perspective from the Los Alamos Fellows" (PDF). Los Alamos National Laboratory Report LA-UR-02-7722: 9.
  18. ^ Hosein ID, Liddell CM (August 2007). "Convectively assembled nonspherical mushroom cap-based colloidal crystals". Langmuir. 23 (17): 8810–4. doi:10.1021/la700865t. PMID 17630788.
  19. ^ Hosein ID, Liddell CM (October 2007). "Convectively assembled asymmetric dimer-based colloidal crystals". Langmuir. 23 (21): 10479–85. doi:10.1021/la7007254. PMID 17629310.
  20. ^ Lee JA, Meng L, Norris DJ, Scriven LE, Tsapatsis M (June 2006). "Colloidal crystal layers of hexagonal nanoplates by convective assembly". Langmuir. 22 (12): 5217–9. doi:10.1021/la0601206. PMID 16732640.
  21. ^ Harper ES, van Anders G, Glotzer SC (August 2019). "The entropic bond in colloidal crystals". Proceedings of the National Academy of Sciences of the United States of America. 116 (34): 16703–16710. Bibcode:2019PNAS..11616703H. doi:10.1073/pnas.1822092116. PMC 6708323. PMID 31375631.
  22. ^ Whitesides GM, Boncheva M (April 2002). "Beyond molecules: self-assembly of mesoscopic and macroscopic components". Proceedings of the National Academy of Sciences of the United States of America. 99 (8): 4769–74. Bibcode:2002PNAS...99.4769W. doi:10.1073/pnas.082065899. PMC 122665. PMID 11959929.
  23. ^ Whitesides GM, Kriebel JK, Love JC (2005). "Molecular engineering of surfaces using self-assembled monolayers" (PDF). Science Progress. 88 (Pt 1): 17–48. CiteSeerX 10.1.1.668.2591. doi:10.3184/003685005783238462. PMC 10367539. PMID 16372593. S2CID 46367976.
  24. ^ Berillo D, Mattiasson B, Galaev IY, Kirsebom H (February 2012). "Formation of macroporous self-assembled hydrogels through cryogelation of Fmoc-Phe-Phe". Journal of Colloid and Interface Science. 368 (1): 226–30. Bibcode:2012JCIS..368..226B. doi:10.1016/j.jcis.2011.11.006. PMID 22129632.
  25. ^ Chen P, Luo Z, Güven S, Tasoglu S, Ganesan AV, Weng A, Demirci U (September 2014). "Microscale assembly directed by liquid-based template". Advanced Materials. 26 (34): 5936–41. doi:10.1002/adma.201402079. PMC 4159433. PMID 24956442.
  26. ^ Yasuga, Hiroki; Iseri, Emre; Wei, Xi; Kaya, Kerem; Di Dio, Giacomo; Osaki, Toshihisa; Kamiya, Koki; Nikolakopoulou, Polyxeni; Buchmann, Sebastian; Sundin, Johan; Bagheri, Shervin; Takeuchi, Shoji; Herland, Anna; Miki, Norihisa; van der Wijngaart, Wouter (2021). "Fluid interfacial energy drives the emergence of three-dimensional periodic structures in micropillar scaffolds". Nature Physics. 17 (7): 794–800. Bibcode:2021NatPh..17..794Y. doi:10.1038/s41567-021-01204-4. ISSN 1745-2473. S2CID 233702358.
  27. ^ Myllymäki TT, Yang H, Liljeström V, Kostiainen MA, Malho JM, Zhu XX, Ikkala O (September 2016). "Hydrogen bonding asymmetric star-shape derivative of bile acid leads to supramolecular fibrillar aggregates that wrap into micrometer spheres". Soft Matter. 12 (34): 7159–65. Bibcode:2016SMat...12.7159M. doi:10.1039/C6SM01329E. PMC 5322467. PMID 27491728.
  28. ^ Ozin GA, Arsenault AC (2005). Nanochemistry: a chemical approach to nanomaterials. Cambridge: Royal Society of Chemistry. ISBN 978-0-85404-664-5.
  29. ^ Velev OD, Denkov ND, Kralchevsky PA, Ivanov IB, Yoshimura H, Nagayama K (1992). "Mechanism of formation of two-dimensional crystals from latex particles on substrates". Langmuir. 8 (12): 3183–3190. doi:10.1021/la00048a054.
  30. ^ Lehn JM (March 2002). "Toward self-organization and complex matter". Science. 295 (5564): 2400–3. Bibcode:2002Sci...295.2400L. doi:10.1126/science.1071063. PMID 11923524. S2CID 37836839.
  31. ^ Forster PM, Cheetham AK (2002). "Open-Framework Nickel Succinate, [Ni7(C4H4O4)6(OH)2(H2O)2]⋅2H2O: A New Hybrid Material with Three-Dimensional Ni−O−Ni Connectivity". Angewandte Chemie International Edition. 41 (3): 457–459. doi:10.1002/1521-3773(20020201)41:3<457::AID-ANIE457>3.0.CO;2-W. PMID 12491377.
  32. ^ Gazit O, Khalfin R, Cohen Y, Tannenbaum R (2009). "Self-Assembled Diblock Copolymer "Nanoreactors" as "Catalysts" for Metal Nanoparticle Synthesis". The Journal of Physical Chemistry C. 113 (2): 576–583. doi:10.1021/jp807668h.
  33. ^ Uskoković V (September 2008). "Isn't self-assembly a misnomer? Multi-disciplinary arguments in favor of co-assembly". Advances in Colloid and Interface Science. 141 (1–2): 37–47. doi:10.1016/j.cis.2008.02.004. PMID 18406396.
  34. ^ Ariga K, Hill JP, Lee MV, Vinu A, Charvet R, Acharya S (January 2008). "Challenges and breakthroughs in recent research on self-assembly". Science and Technology of Advanced Materials. 9 (1): 014109. Bibcode:2008STAdM...9a4109A. doi:10.1088/1468-6996/9/1/014109. PMC 5099804. PMID 27877935.
  35. ^ Ariga K, Nishikawa M, Mori T, Takeya J, Shrestha LK, Hill JP (2019). "Self-assembly as a key player for materials nanoarchitectonics". Science and Technology of Advanced Materials. 20 (1): 51–95. Bibcode:2019STAdM..20...51A. doi:10.1080/14686996.2018.1553108. PMC 6374972. PMID 30787960.
  36. ^ Talapin DV, Shevchenko EV, Bodnarchuk MI, Ye X, Chen J, Murray CB (October 2009). "Quasicrystalline order in self-assembled binary nanoparticle superlattices". Nature. 461 (7266): 964–7. Bibcode:2009Natur.461..964T. doi:10.1038/nature08439. PMID 19829378. S2CID 4344953.
  37. ^ Nagaoka Y, Zhu H, Eggert D, Chen O (December 2018). "Single-component quasicrystalline nanocrystal superlattices through flexible polygon tiling rule". Science. 362 (6421): 1396–1400. Bibcode:2018Sci...362.1396N. doi:10.1126/science.aav0790. hdl:21.11116/0000-0002-B8DF-4. PMID 30573624.
  38. ^ Saha, Abhijit; Bolisetty, Sreenath; Handschin, Stephan; Mezzenga, Raffaele (2013). "Self-assembly and fibrillization of a Fmoc-functionalized polyphenolic amino acid". Soft Matter. 9 (43): 10239. Bibcode:2013SMat....910239S. doi:10.1039/c3sm52222a. ISSN 1744-683X.
  39. ^ Fichman, Galit; Guterman, Tom; Adler-Abramovich, Lihi; Gazit, Ehud (2015). "Synergetic functional properties of two-component single amino acid-based hydrogels". CrystEngComm. 17 (42): 8105–8112. doi:10.1039/C5CE01051A. ISSN 1466-8033.
  40. ^ Fichman, Galit; Guterman, Tom; Damron, Joshua; Adler-Abramovich, Lihi; Schmidt, Judith; Kesselman, Ellina; Shimon, Linda J. W.; Ramamoorthy, Ayyalusamy; Talmon, Yeshayahu; Gazit, Ehud (2016-02-05). "Spontaneous structural transition and crystal formation in minimal supramolecular polymer model". Science Advances. 2 (2): e1500827. Bibcode:2016SciA....2E0827F. doi:10.1126/sciadv.1500827. ISSN 2375-2548. PMC 4758747. PMID 26933679.
  41. ^ Hosokawa K, Shimoyama I, Miura H (1994). "Dynamics of self-assembling systems: Analogy with chemical kinetics". Artificial Life. 1 (4): 413–427. doi:10.1162/artl.1994.1.413.
  42. ^ Groß R, Bonani M, Mondada F, Dorigo M (2006). "Autonomous self-assembly in swarm-bots". IEEE Transactions on Robotics. 22 (6): 1115–1130. doi:10.1109/TRO.2006.882919. S2CID 606998.
  43. ^ Groß R, Dorigo M (2008). "Self-assembly at the macroscopic scale". Proceedings of the IEEE. 96 (9): 1490–1508. CiteSeerX 10.1.1.145.8984. doi:10.1109/JPROC.2008.927352. S2CID 7094751. from the original on Nov 18, 2023.
  44. ^ Stephenson C, Lyon D, Hübler A (February 2017). "Topological properties of a self-assembled electrical network via ab initio calculation". Scientific Reports. 7: 41621. Bibcode:2017NatSR...741621S. doi:10.1038/srep41621. PMC 5290745. PMID 28155863.
  45. ^ D’Monte, Leslie (7 May 2014). "Indian market sees promise in 3D printers". Mint.
  46. ^ Tibbits, Skylar (February 2013). "The emergence of "4D printing"". TED Talk. from the original on Nov 26, 2021.
  47. ^ Halley JD, Winkler DA (2008). "Consistent Concepts of Self-organization and Self-assembly". Complexity. 14 (2): 10–17. Bibcode:2008Cmplx..14b..10H. doi:10.1002/cplx.20235.
  48. ^ Halley JD, Winkler DA (May 2008). "Critical-like self-organization and natural selection: two facets of a single evolutionary process?". Bio Systems. 92 (2): 148–58. doi:10.1016/j.biosystems.2008.01.005. PMID 18353531. We argue that critical-like dynamics self-organize relatively easily in non-equilibrium systems, and that in biological systems such dynamics serve as templates upon which natural selection builds further elaborations. These critical-like states can be modified by natural selection in two fundamental ways, reflecting the selective advantage (if any) of heritable variations either among avalanche participants or among whole systems.
  49. ^ Halley JD, Winkler DA (2008). "Consistent Concepts of Self-organization and Self-assembly". Complexity. 14 (2): 15. Bibcode:2008Cmplx..14b..10H. doi:10.1002/cplx.20235. [...] it may one day even be possible to integrate these pattern forming mechanisms into the one general theory of pattern formation in nature.

Further reading edit

 
Scholia has a topic profile for Self-assembly.
  • Whitesides GM, Grzybowski B (March 2002). "Self-assembly at all scales". Science. 295 (5564): 2418–21. Bibcode:2002Sci...295.2418W. doi:10.1126/science.1070821. PMID 11923529. S2CID 40684317.
  • Damasceno PF, Engel M, Glotzer SC (July 2012). "Predictive self-assembly of polyhedra into complex structures". Science. 337 (6093): 453–7. Bibcode:2012Sci...337..453D. CiteSeerX 10.1.1.455.6962. doi:10.1126/science.1220869. PMID 22837525. S2CID 7177740.
  • Rothemund PW, Papadakis N, Winfree E (December 2004). "Algorithmic self-assembly of DNA Sierpinski triangles". PLOS Biology. 2 (12): e424. doi:10.1371/journal.pbio.0020424. PMC 534809. PMID 15583715.
  • Stephens AD (1977). "The management of cystinuria in 1976". Proceedings of the Royal Society of Medicine. 70 Suppl 3 (3_suppl): 24–6. doi:10.1177/00359157770700S310. PMC 1543588. PMID 122665.

External links edit

  • Kuniaki Nagayama, Freeview Video 'Self-Assembly: Nature's Way To Do It, A Royal Institution Lecture by the Vega Science Trust.
  • Paper
  • Wiki: C2 Self Assembly from a computer programming perspective.
  • Pelesko, J.A., (2007) Self Assembly: The Science of Things That Put Themselves Together, Chapman & Hall/CRC Press.
  • A brief page on self-assembly at the University of Delaware
  • Structure and Dynamics of Organic Nanostructures
  • Metal organic coordination networks of oligopyridines and Cu on graphite

February 16, 2024
self, assembly, other, uses, self, construction, disambiguation, process, which, disordered, system, existing, components, forms, organized, structure, pattern, consequence, specific, local, interactions, among, components, themselves, without, external, direc. For other uses see Self construction disambiguation Self assembly is a process in which a disordered system of pre existing components forms an organized structure or pattern as a consequence of specific local interactions among the components themselves without external direction When the constitutive components are molecules the process is termed molecular self assembly Self assembly of lipids a proteins b and c SDS cyclodextrin complexes SDS is a surfactant with a hydrocarbon tail yellow and a SO4 head blue and red while cyclodextrin is a saccharide ring green C and red O atoms Transmission electron microscopy image of an iron oxide nanoparticle Regularly arranged dots within the dashed border are columns of Fe atoms Left inset is the corresponding electron diffraction pattern Scale bar 10 nm 1 Iron oxide nanoparticles can be dispersed in an organic solvent toluene Upon its evaporation they may self assemble left and right panels into micron sized mesocrystals center or multilayers right Each dot in the left image is a traditional atomic crystal shown in the image above Scale bars 100 nm left 25 mm center 50 nm right 1 STM image of self assembled Br4 pyrene molecules on Au 111 surface top and its model bottom pink spheres are Br atoms 2 AFM imaging of self assembly of 2 aminoterephthalic acid molecules on 104 oriented calcite 3 Self assembly can be classified as either static or dynamic In static self assembly the ordered state forms as a system approaches equilibrium reducing its free energy However in dynamic self assembly patterns of pre existing components organized by specific local interactions are not commonly described as self assembled by scientists in the associated disciplines These structures are better described as self organized although these terms are often used interchangeably Contents 1 In chemistry and materials science 1 1 Distinctive features 1 1 1 Order 1 1 2 Interactions 1 1 3 Building blocks 1 2 Thermodynamics and kinetics 1 3 Examples 1 4 Properties 2 At the macroscopic scale 3 Consistent concepts of self organization and self assembly 4 See also 5 References 6 Further reading 7 External linksIn chemistry and materials science edit nbsp The DNA structure at left schematic shown will self assemble into the structure visualized by atomic force microscopy at right Self assembly in the classic sense can be defined as the spontaneous and reversible organization of molecular units into ordered structures by non covalent interactions The first property of a self assembled system that this definition suggests is the spontaneity of the self assembly process the interactions responsible for the formation of the self assembled system act on a strictly local level in other words the nanostructure builds itself Although self assembly typically occurs between weakly interacting species this organization may be transferred into strongly bound covalent systems An example for this may be observed in the self assembly of polyoxometalates Evidence suggests that such molecules assemble via a dense phase type mechanism whereby small oxometalate ions first assemble non covalently in solution followed by a condensation reaction that covalently binds the assembled units 4 This process can be aided by the introduction of templating agents to control the formed species 5 In such a way highly organized covalent molecules may be formed in a specific manner Self assembled nano structure is an object that appears as a result of ordering and aggregation of individual nano scale objects guided by some physical principle A particularly counter intuitive example of a physical principle that can drive self assembly is entropy maximization Though entropy is conventionally associated with disorder under suitable conditions 6 entropy can drive nano scale objects to self assemble into target structures in a controllable way 7 Another important class of self assembly is field directed assembly An example of this is the phenomenon of electrostatic trapping In this case an electric field is applied between two metallic nano electrodes The particles present in the environment are polarized by the applied electric field Because of dipole interaction with the electric field gradient the particles are attracted to the gap between the electrodes 8 Generalizations of this type approach involving different types of fields e g using magnetic fields using capillary interactions for particles trapped at interfaces elastic interactions for particles suspended in liquid crystals have also been reported Regardless of the mechanism driving self assembly people take self assembly approaches to materials synthesis to avoid the problem of having to construct materials one building block at a time Avoiding one at a time approaches is important because the amount of time required to place building blocks into a target structure is prohibitively difficult for structures that have macroscopic size Once materials of macroscopic size can be self assembled those materials can find use in many applications For example nano structures such as nano vacuum gaps are used for storing energy 9 and nuclear energy conversion 10 Self assembled tunable materials are promising candidates for large surface area electrodes in batteries and organic photovoltaic cells as well as for microfluidic sensors and filters 11 Distinctive features edit At this point one may argue that any chemical reaction driving atoms and molecules to assemble into larger structures such as precipitation could fall into the category of self assembly However there are at least three distinctive features that make self assembly a distinct concept Order edit First the self assembled structure must have a higher order than the isolated components be it a shape or a particular task that the self assembled entity may perform This is generally not true in chemical reactions where an ordered state may proceed towards a disordered state depending on thermodynamic parameters Interactions edit The second important aspect of self assembly is the predominant role of weak interactions e g Van der Waals capillary p p displaystyle pi pi nbsp hydrogen bonds or entropic forces compared to more traditional covalent ionic or metallic bonds These weak interactions are important in materials synthesis for two reasons First weak interactions take a prominent place in materials especially in biological systems For instance they determine the physical properties of liquids the solubility of solids and the organization of molecules in biological membranes 12 Second in addition to the strength of the interactions interactions with varying degrees of specificity can control self assembly Self assembly that is mediated by DNA pairing interactions constitutes the interactions of the highest specificity that have been used to drive self assembly 13 At the other extreme the least specific interactions are possibly those provided by emergent forces that arise from entropy maximization 6 Building blocks edit The third distinctive feature of self assembly is that the building blocks are not only atoms and molecules but span a wide range of nano and mesoscopic structures with different chemical compositions functionalities 14 and shapes 15 Research into possible three dimensional shapes of self assembling micrites examines Platonic solids regular polyhedral The term micrite was created by DARPA to refer to sub millimeter sized microrobots whose self organizing abilities may be compared with those of slime mold 16 17 Recent examples of novel building blocks include polyhedra and patchy particles 14 Examples also included microparticles with complex geometries such as hemispherical 18 dimer 19 discs 20 rods molecules as well as multimers These nanoscale building blocks can in turn be synthesized through conventional chemical routes or by other self assembly strategies such as directional entropic forces More recently inverse design approaches have appeared where it is possible to fix a target self assembled behavior and determine an appropriate building block that will realize that behavior 7 Thermodynamics and kinetics edit Self assembly in microscopic systems usually starts from diffusion followed by the nucleation of seeds subsequent growth of the seeds and ends at Ostwald ripening The thermodynamic driving free energy can be either enthalpic or entropic or both 6 In either the enthalpic or entropic case self assembly proceeds through the formation and breaking of bonds 21 possibly with non traditional forms of mediation The kinetics of the self assembly process is usually related to diffusion for which the absorption adsorption rate often follows a Langmuir adsorption model which in the diffusion controlled concentration relatively diluted solution can be estimated by the Fick s laws of diffusion The desorption rate is determined by the bond strength of the surface molecules atoms with a thermal activation energy barrier The growth rate is the competition between these two processes Examples edit Important examples of self assembly in materials science include the formation of molecular crystals colloids lipid bilayers phase separated polymers and self assembled monolayers 22 23 The folding of polypeptide chains into proteins and the folding of nucleic acids into their functional forms are examples of self assembled biological structures Recently the three dimensional macroporous structure was prepared via self assembly of diphenylalanine derivative under cryoconditions the obtained material can find the application in the field of regenerative medicine or drug delivery system 24 P Chen et al demonstrated a microscale self assembly method using the air liquid interface established by Faraday wave as a template This self assembly method can be used for generation of diverse sets of symmetrical and periodic patterns from microscale materials such as hydrogels cells and cell spheroids 25 Yasuga et al demonstrated how fluid interfacial energy drives the emergence of three dimensional periodic structures in micropillar scaffolds 26 Myllymaki et al demonstrated the formation of micelles that undergo a change in morphology to fibers and eventually to spheres all controlled by solvent change 27 Properties edit Self assembly extends the scope of chemistry aiming at synthesizing products with order and functionality properties extending chemical bonds to weak interactions and encompassing the self assembly of nanoscale building blocks at all length scales 28 In covalent synthesis and polymerization the scientist links atoms together in any desired conformation which does not necessarily have to be the energetically most favoured position self assembling molecules on the other hand adopt a structure at the thermodynamic minimum finding the best combination of interactions between subunits but not forming covalent bonds between them In self assembling structures the scientist must predict this minimum not merely place the atoms in the location desired Another characteristic common to nearly all self assembled systems is their thermodynamic stability For self assembly to take place without intervention of external forces the process must lead to a lower Gibbs free energy thus self assembled structures are thermodynamically more stable than the single unassembled components A direct consequence is the general tendency of self assembled structures to be relatively free of defects An example is the formation of two dimensional superlattices composed of an orderly arrangement of micrometre sized polymethylmethacrylate PMMA spheres starting from a solution containing the microspheres in which the solvent is allowed to evaporate slowly in suitable conditions In this case the driving force is capillary interaction which originates from the deformation of the surface of a liquid caused by the presence of floating or submerged particles 29 These two properties weak interactions and thermodynamic stability can be recalled to rationalise another property often found in self assembled systems the sensitivity to perturbations exerted by the external environment These are small fluctuations that alter thermodynamic variables that might lead to marked changes in the structure and even compromise it either during or after self assembly The weak nature of interactions is responsible for the flexibility of the architecture and allows for rearrangements of the structure in the direction determined by thermodynamics If fluctuations bring the thermodynamic variables back to the starting condition the structure is likely to go back to its initial configuration This leads us to identify one more property of self assembly which is generally not observed in materials synthesized by other techniques reversibility Self assembly is a process which is easily influenced by external parameters This feature can make synthesis rather complex because of the need to control many free parameters Yet self assembly has the advantage that a large variety of shapes and functions on many length scales can be obtained 30 The fundamental condition needed for nanoscale building blocks to self assemble into an ordered structure is the simultaneous presence of long range repulsive and short range attractive forces 31 By choosing precursors with suitable physicochemical properties it is possible to exert a fine control on the formation processes that produce complex structures Clearly the most important tool when it comes to designing a synthesis strategy for a material is the knowledge of the chemistry of the building units For example it was demonstrated that it was possible to use diblock copolymers with different block reactivities in order to selectively embed maghemite nanoparticles and generate periodic materials with potential use as waveguides 32 In 2008 it was proposed that every self assembly process presents a co assembly which makes the former term a misnomer This thesis is built on the concept of mutual ordering of the self assembling system and its environment 33 At the macroscopic scale editThe most common examples of self assembly at the macroscopic scale can be seen at interfaces between gases and liquids where molecules can be confined at the nanoscale in the vertical direction and spread over long distances laterally Examples of self assembly at gas liquid interfaces include breath figures self assembled monolayers droplet clusters and Langmuir Blodgett films while crystallization of fullerene whiskers is an example of macroscopic self assembly in between two liquids 34 35 Another remarkable example of macroscopic self assembly is the formation of thin quasicrystals at an air liquid interface which can be built up not only by inorganic but also by organic molecular units 36 37 Furthermore it was reported that Fmoc protected L DOPA amino acid Fmoc DOPA 38 39 can present a minimal supramolecular polymer model displaying a spontaneous structural transition from meta stable spheres to fibrillar assemblies to gel like material and finally to single crystals 40 Self assembly processes can also be observed in systems of macroscopic building blocks These building blocks can be externally propelled 41 or self propelled 42 Since the 1950s scientists have built self assembly systems exhibiting centimeter sized components ranging from passive mechanical parts to mobile robots 43 For systems at this scale the component design can be precisely controlled For some systems the components interaction preferences are programmable The self assembly processes can be easily monitored and analyzed by the components themselves or by external observers 44 In April 2014 a 3D printed plastic was combined with a smart material that self assembles in water 45 resulting in 4D printing 46 Consistent concepts of self organization and self assembly editPeople regularly use the terms self organization and self assembly interchangeably As complex system science becomes more popular though there is a higher need to clearly distinguish the differences between the two mechanisms to understand their significance in physical and biological systems Both processes explain how collective order develops from dynamic small scale interactions 47 Self organization is a non equilibrium process where self assembly is a spontaneous process that leads toward equilibrium Self assembly requires components to remain essentially unchanged throughout the process Besides the thermodynamic difference between the two there is also a difference in formation The first difference is what encodes the global order of the whole in self assembly whereas in self organization this initial encoding is not necessary Another slight contrast refers to the minimum number of units needed to make an order Self organization appears to have a minimum number of units whereas self assembly does not The concepts may have particular application in connection with natural selection 48 Eventually these patterns may form one theory of pattern formation in nature 49 See also editAssembly theory Crystal engineering Autopoiesis Langmuir Blodgett film Nanotechnology Pick and place machine Self assembly of nanoparticles 3D microfabrication Self folding materialsReferences edit a b Wetterskog E Agthe M Mayence A Grins J Wang D Rana S et al October 2014 Precise control over shape and size of iron oxide nanocrystals suitable for assembly into ordered particle arrays Science and Technology of Advanced Materials 15 5 055010 Bibcode 2014STAdM 15e5010W doi 10 1088 1468 6996 15 5 055010 PMC 5099683 PMID 27877722 Pham TA Song F Nguyen MT Stohr M November 2014 Self assembly of pyrene derivatives on Au 111 substituent effects on intermolecular interactions Chemical Communications 50 91 14089 92 doi 10 1039 C4CC02753A PMID 24905327 Kling F 2016 Diffusion and structure formation of molecules on calcite 104 PhD Johannes Gutenberg University Mainz doi 10 25358 openscience 2179 Schreiber RE Avram L Neumann R January 2018 Self Assembly through Noncovalent Preorganization of Reactants Explaining the Formation of a Polyfluoroxometalate Chemistry A European Journal 24 2 369 379 doi 10 1002 chem 201704287 PMID 29064591 Miras HN Cooper GJ Long DL Bogge H Muller A Streb C Cronin L January 2010 Unveiling the transient template in the self assembly of a molecular oxide nanowheel Science 327 5961 72 4 Bibcode 2010Sci 327 72M doi 10 1126 science 1181735 PMID 20044572 S2CID 24736211 a b c van Anders G Klotsa D Ahmed NK Engel M Glotzer SC November 2014 Understanding shape entropy through local dense packing Proceedings of the National Academy of Sciences of the United States of America 111 45 E4812 21 arXiv 1309 1187 Bibcode 2014PNAS 111E4812V doi 10 1073 pnas 1418159111 PMC 4234574 PMID 25344532 a b Geng Y van Anders G Dodd PM Dshemuchadse J Glotzer SC July 2019 Engineering entropy for the inverse design of colloidal crystals from hard shapes Science Advances 5 7 eaaw0514 arXiv 1712 02471 Bibcode 2019SciA 5 514G doi 10 1126 sciadv aaw0514 PMC 6611692 PMID 31281885 Bezryadin A Westervelt RM Tinkham M 1999 Self assembled chains of graphitized carbon nanoparticles Applied Physics Letters 74 18 2699 2701 arXiv cond mat 9810235 Bibcode 1999ApPhL 74 2699B doi 10 1063 1 123941 S2CID 14398155 Lyon D Hubler A 2013 Gap size dependence of the dielectric strength in nano vacuum gaps IEEE Transactions on Dielectrics and Electrical Insulation 20 4 1467 1471 doi 10 1109 TDEI 2013 6571470 S2CID 709782 Shinn E 2012 Nuclear energy conversion with stacks of graphene nanocapacitors Complexity 18 3 24 27 Bibcode 2013Cmplx 18c 24S doi 10 1002 cplx 21427 Demortiere A Snezhko A Sapozhnikov MV Becker N Proslier T Aranson IS 2014 Self assembled tunable networks of sticky colloidal particles Nature Communications 5 3117 Bibcode 2014NatCo 5 3117D doi 10 1038 ncomms4117 PMID 24445324 Israelachvili JN 2011 Intermolecular and Surface Forces 3rd ed Elsevier Jones MR Seeman NC Mirkin CA February 2015 Nanomaterials Programmable materials and the nature of the DNA bond Science 347 6224 1260901 doi 10 1126 science 1260901 PMID 25700524 a b Glotzer SC Solomon MJ August 2007 Anisotropy of building blocks and their assembly into complex structures Nature Materials 6 8 557 62 doi 10 1038 nmat1949 PMID 17667968 van Anders G Ahmed NK Smith R Engel M Glotzer SC January 2014 Entropically patchy particles engineering valence through shape entropy ACS Nano 8 1 931 40 arXiv 1304 7545 doi 10 1021 nn4057353 PMID 24359081 S2CID 9669569 Solem JC 2002 Self assembling micrites based on the Platonic solids Robotics and Autonomous Systems 38 2 69 92 doi 10 1016 s0921 8890 01 00167 1 Trewhella J Solem JC 1998 Future Research Directions for Los Alamos A Perspective from the Los Alamos Fellows PDF Los Alamos National Laboratory Report LA UR 02 7722 9 Hosein ID Liddell CM August 2007 Convectively assembled nonspherical mushroom cap based colloidal crystals Langmuir 23 17 8810 4 doi 10 1021 la700865t PMID 17630788 Hosein ID Liddell CM October 2007 Convectively assembled asymmetric dimer based colloidal crystals Langmuir 23 21 10479 85 doi 10 1021 la7007254 PMID 17629310 Lee JA Meng L Norris DJ Scriven LE Tsapatsis M June 2006 Colloidal crystal layers of hexagonal nanoplates by convective assembly Langmuir 22 12 5217 9 doi 10 1021 la0601206 PMID 16732640 Harper ES van Anders G Glotzer SC August 2019 The entropic bond in colloidal crystals Proceedings of the National Academy of Sciences of the United States of America 116 34 16703 16710 Bibcode 2019PNAS 11616703H doi 10 1073 pnas 1822092116 PMC 6708323 PMID 31375631 Whitesides GM Boncheva M April 2002 Beyond molecules self assembly of mesoscopic and macroscopic components Proceedings of the National Academy of Sciences of the United States of America 99 8 4769 74 Bibcode 2002PNAS 99 4769W doi 10 1073 pnas 082065899 PMC 122665 PMID 11959929 Whitesides GM Kriebel JK Love JC 2005 Molecular engineering of surfaces using self assembled monolayers PDF Science Progress 88 Pt 1 17 48 CiteSeerX 10 1 1 668 2591 doi 10 3184 003685005783238462 PMC 10367539 PMID 16372593 S2CID 46367976 Berillo D Mattiasson B Galaev IY Kirsebom H February 2012 Formation of macroporous self assembled hydrogels through cryogelation of Fmoc Phe Phe Journal of Colloid and Interface Science 368 1 226 30 Bibcode 2012JCIS 368 226B doi 10 1016 j jcis 2011 11 006 PMID 22129632 Chen P Luo Z Guven S Tasoglu S Ganesan AV Weng A Demirci U September 2014 Microscale assembly directed by liquid based template Advanced Materials 26 34 5936 41 doi 10 1002 adma 201402079 PMC 4159433 PMID 24956442 Yasuga Hiroki Iseri Emre Wei Xi Kaya Kerem Di Dio Giacomo Osaki Toshihisa Kamiya Koki Nikolakopoulou Polyxeni Buchmann Sebastian Sundin Johan Bagheri Shervin Takeuchi Shoji Herland Anna Miki Norihisa van der Wijngaart Wouter 2021 Fluid interfacial energy drives the emergence of three dimensional periodic structures in micropillar scaffolds Nature Physics 17 7 794 800 Bibcode 2021NatPh 17 794Y doi 10 1038 s41567 021 01204 4 ISSN 1745 2473 S2CID 233702358 Myllymaki TT Yang H Liljestrom V Kostiainen MA Malho JM Zhu XX Ikkala O September 2016 Hydrogen bonding asymmetric star shape derivative of bile acid leads to supramolecular fibrillar aggregates that wrap into micrometer spheres Soft Matter 12 34 7159 65 Bibcode 2016SMat 12 7159M doi 10 1039 C6SM01329E PMC 5322467 PMID 27491728 Ozin GA Arsenault AC 2005 Nanochemistry a chemical approach to nanomaterials Cambridge Royal Society of Chemistry ISBN 978 0 85404 664 5 Velev OD Denkov ND Kralchevsky PA Ivanov IB Yoshimura H Nagayama K 1992 Mechanism of formation of two dimensional crystals from latex particles on substrates Langmuir 8 12 3183 3190 doi 10 1021 la00048a054 Lehn JM March 2002 Toward self organization and complex matter Science 295 5564 2400 3 Bibcode 2002Sci 295 2400L doi 10 1126 science 1071063 PMID 11923524 S2CID 37836839 Forster PM Cheetham AK 2002 Open Framework Nickel Succinate Ni7 C4H4O4 6 OH 2 H2O 2 2H2O A New Hybrid Material with Three Dimensional Ni O Ni Connectivity Angewandte Chemie International Edition 41 3 457 459 doi 10 1002 1521 3773 20020201 41 3 lt 457 AID ANIE457 gt 3 0 CO 2 W PMID 12491377 Gazit O Khalfin R Cohen Y Tannenbaum R 2009 Self Assembled Diblock Copolymer Nanoreactors as Catalysts for Metal Nanoparticle Synthesis The Journal of Physical Chemistry C 113 2 576 583 doi 10 1021 jp807668h Uskokovic V September 2008 Isn t self assembly a misnomer Multi disciplinary arguments in favor of co assembly Advances in Colloid and Interface Science 141 1 2 37 47 doi 10 1016 j cis 2008 02 004 PMID 18406396 Ariga K Hill JP Lee MV Vinu A Charvet R Acharya S January 2008 Challenges and breakthroughs in recent research on self assembly Science and Technology of Advanced Materials 9 1 014109 Bibcode 2008STAdM 9a4109A doi 10 1088 1468 6996 9 1 014109 PMC 5099804 PMID 27877935 Ariga K Nishikawa M Mori T Takeya J Shrestha LK Hill JP 2019 Self assembly as a key player for materials nanoarchitectonics Science and Technology of Advanced Materials 20 1 51 95 Bibcode 2019STAdM 20 51A doi 10 1080 14686996 2018 1553108 PMC 6374972 PMID 30787960 Talapin DV Shevchenko EV Bodnarchuk MI Ye X Chen J Murray CB October 2009 Quasicrystalline order in self assembled binary nanoparticle superlattices Nature 461 7266 964 7 Bibcode 2009Natur 461 964T doi 10 1038 nature08439 PMID 19829378 S2CID 4344953 Nagaoka Y Zhu H Eggert D Chen O December 2018 Single component quasicrystalline nanocrystal superlattices through flexible polygon tiling rule Science 362 6421 1396 1400 Bibcode 2018Sci 362 1396N doi 10 1126 science aav0790 hdl 21 11116 0000 0002 B8DF 4 PMID 30573624 Saha Abhijit Bolisetty Sreenath Handschin Stephan Mezzenga Raffaele 2013 Self assembly and fibrillization of a Fmoc functionalized polyphenolic amino acid Soft Matter 9 43 10239 Bibcode 2013SMat 910239S doi 10 1039 c3sm52222a ISSN 1744 683X Fichman Galit Guterman Tom Adler Abramovich Lihi Gazit Ehud 2015 Synergetic functional properties of two component single amino acid based hydrogels CrystEngComm 17 42 8105 8112 doi 10 1039 C5CE01051A ISSN 1466 8033 Fichman Galit Guterman Tom Damron Joshua Adler Abramovich Lihi Schmidt Judith Kesselman Ellina Shimon Linda J W Ramamoorthy Ayyalusamy Talmon Yeshayahu Gazit Ehud 2016 02 05 Spontaneous structural transition and crystal formation in minimal supramolecular polymer model Science Advances 2 2 e1500827 Bibcode 2016SciA 2E0827F doi 10 1126 sciadv 1500827 ISSN 2375 2548 PMC 4758747 PMID 26933679 Hosokawa K Shimoyama I Miura H 1994 Dynamics of self assembling systems Analogy with chemical kinetics Artificial Life 1 4 413 427 doi 10 1162 artl 1994 1 413 Gross R Bonani M Mondada F Dorigo M 2006 Autonomous self assembly in swarm bots IEEE Transactions on Robotics 22 6 1115 1130 doi 10 1109 TRO 2006 882919 S2CID 606998 Gross R Dorigo M 2008 Self assembly at the macroscopic scale Proceedings of the IEEE 96 9 1490 1508 CiteSeerX 10 1 1 145 8984 doi 10 1109 JPROC 2008 927352 S2CID 7094751 Archived from the original on Nov 18 2023 Stephenson C Lyon D Hubler A February 2017 Topological properties of a self assembled electrical network via ab initio calculation Scientific Reports 7 41621 Bibcode 2017NatSR 741621S doi 10 1038 srep41621 PMC 5290745 PMID 28155863 D Monte Leslie 7 May 2014 Indian market sees promise in 3D printers Mint Tibbits Skylar February 2013 The emergence of 4D printing TED Talk Archived from the original on Nov 26 2021 Halley JD Winkler DA 2008 Consistent Concepts of Self organization and Self assembly Complexity 14 2 10 17 Bibcode 2008Cmplx 14b 10H doi 10 1002 cplx 20235 Halley JD Winkler DA May 2008 Critical like self organization and natural selection two facets of a single evolutionary process Bio Systems 92 2 148 58 doi 10 1016 j biosystems 2008 01 005 PMID 18353531 We argue that critical like dynamics self organize relatively easily in non equilibrium systems and that in biological systems such dynamics serve as templates upon which natural selection builds further elaborations These critical like states can be modified by natural selection in two fundamental ways reflecting the selective advantage if any of heritable variations either among avalanche participants or among whole systems Halley JD Winkler DA 2008 Consistent Concepts of Self organization and Self assembly Complexity 14 2 15 Bibcode 2008Cmplx 14b 10H doi 10 1002 cplx 20235 it may one day even be possible to integrate these pattern forming mechanisms into the one general theory of pattern formation in nature Further reading edit nbsp Scholia has a topic profile for Self assembly Whitesides GM Grzybowski B March 2002 Self assembly at all scales Science 295 5564 2418 21 Bibcode 2002Sci 295 2418W doi 10 1126 science 1070821 PMID 11923529 S2CID 40684317 Damasceno PF Engel M Glotzer SC July 2012 Predictive self assembly of polyhedra into complex structures Science 337 6093 453 7 Bibcode 2012Sci 337 453D CiteSeerX 10 1 1 455 6962 doi 10 1126 science 1220869 PMID 22837525 S2CID 7177740 Rothemund PW Papadakis N Winfree E December 2004 Algorithmic self assembly of DNA Sierpinski triangles PLOS Biology 2 12 e424 doi 10 1371 journal pbio 0020424 PMC 534809 PMID 15583715 Stephens AD 1977 The management of cystinuria in 1976 Proceedings of the Royal Society of Medicine 70 Suppl 3 3 suppl 24 6 doi 10 1177 00359157770700S310 PMC 1543588 PMID 122665 External links editKuniaki Nagayama Freeview Video Self Assembly Nature s Way To Do It A Royal Institution Lecture by the Vega Science Trust Paper Molecular Self Assembly Wiki C2 Self Assembly from a computer programming perspective Pelesko J A 2007 Self Assembly The Science of Things That Put Themselves Together Chapman amp Hall CRC Press A brief page on self assembly at the University of Delaware Self Assembly Structure and Dynamics of Organic Nanostructures Metal organic coordination networks of oligopyridines and Cu on graphite Retrieved from https en wikipedia org w index php title Self assembly amp oldid 1193590798, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.