ADDITIVE MANUFACTURING OF SELF-ORGANIZED CRYSTAL STRUCTURES AS NOVEL MATERIALS FOR SENSOR MESOFLUIDIC CHIPS BASED ON LAYER-BY-LAYER GROWTH AND THEIR MICROCRYSTALLOMORPHOLOGICAL ANALYSIS
( Pp. 172-174)
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Gradov Oleg Valeryevich
research fellow, Photobionics Laboratory (0412), Department of Dynamics of Biological and Chemical Processes; senior researcher / senior research fellow, Laboratory of Biological Effects of Nanostructures (005)
N.N. Semenov Institute of Chemical Physics, Russian Academy of Sciences; V.L. Talrose Institute for Energy Problems of Chemical Physics (Russian Academy of Sciences) Gradova Margaret Alekseevna starshiy nauchnyy sotrudnik, laboratoriya fotobioniki (0412), otdel dinamiki himicheskih i biologicheskih processov
N.N. Semenov Institute of Chemical Physics, Russian Academy of Sciences
N.N. Semenov Institute of Chemical Physics, Russian Academy of Sciences; V.L. Talrose Institute for Energy Problems of Chemical Physics (Russian Academy of Sciences) Gradova Margaret Alekseevna starshiy nauchnyy sotrudnik, laboratoriya fotobioniki (0412), otdel dinamiki himicheskih i biologicheskih processov
N.N. Semenov Institute of Chemical Physics, Russian Academy of Sciences
Abstract:
Here we propose a novel approach towards lab-on-a-chip manufacturing combining synthesis of the chip material with its geometry formation controlled by the physical and chemical properties of its material, which are in these manufacturing conditions inseparable from its particular geometry arising from the principles of crystallography and microcrystallomorphological analysis. In this case, the problems of the chip assembly are replaced by the problems of the layered coating growth on the substrate, while the multilayer material formation provides the programmable variation of the resulting chip properties determined by the number and geometry of the converter layers. The chip / surface geometry is optimized by the free energy minimization in the course of conservative layer-by-layer (LBL) self-assembly process.
How to Cite:
Gradov O.V., Gradova M.A., (2018), ADDITIVE MANUFACTURING OF SELF-ORGANIZED CRYSTAL STRUCTURES AS NOVEL MATERIALS FOR SENSOR MESOFLUIDIC CHIPS BASED ON LAYER-BY-LAYER GROWTH AND THEIR MICROCRYSTALLOMORPHOLOGICAL ANALYSIS. Computational Nanotechnology, 1 => 172-174.
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Gradov O.V. (2017) Multi-functional microprobe lab-on-a-chip based on the active-pixel sensor with the position-sensitive cassette masks assembled from discrete converters of different biophysical and biochemical parameters into the optical response signals. International Journal of Modern Physics. 1: 23-28.
Yang J.K.W., Jung Y.S., Chang J.B. et al. (2010) Complex self-assembled patterns using sparse commensurate templates with locally varying motifs. Nature Nanotechnology. 5: 256-260.
Smits E.C.P., Mathijssen S.G.J., van Hal P.A. et al. (2008) Bottom-up organic integrated circuits. Nature. 455 (7215): 956-959.
Chang J.-B., Choi H.K., Hannon A.F. et al. (2014). Design rules for self-assembled block copolymer patterns using tiled templates. Nature Communications. 5: 3305.
Bita I., Yang J.K., Jung Y.S. et al. (2008) Graphoepitaxy of self-assembled block copolymers on two-dimensional periodic patterned templates. Science. 321 (5891): 939-943.
Jung Y.S., Chang J.B., Verploegen E. et al. (2010) A path to ultranarrow patterns using self-assembled lithography. Nano Letters. 10 (3): 1000-1005.
Trumler W., Schlingmann S., Ungerer T. et al. (2008) Self-optimized Routing in a Network on-a-Chip. In: Biologically-Inspired Collaborative Computing. B., Springer: 199-212.
Collet J.H., Zajac P., Psarakis M. et al. (2011) Chip self-organizati and fault tolerance in massively defecti e multi ore arrays. IEEE Transacti on Dependable and Secure Computi. 8 (2): 207-217.
Feklichev V.G. (1966) Microcrystallomorphological analysis, Moscow: Science, 200 p.
Feklichev V.G. (1970) Microcrystallomorphological research, Moscow: Science, 176 p.
Keller S.W., Kim H.N., Mallouk T.E. (1994) Layer-by-Layer Assembly of intercalation compounds and heterostructures on surfaces: Toward molecular beaker epitaxy. Journal of the American Chemical Society. 116 (19): 8817-8818.
Abe M., Michi T., Sato A. et al. (2003) Electrochemically Controlled Layer-by-Layer Deposition of Metal-Cluster Molecular Multilayers on Gold. Angewandte Chemie International Edition. 42 (25): 2912-2915.
Kunkel R., Poelsema B., Verheij L.K. et al. (1990) Reentrant layer-by-layer growth during molecular-beam epitaxy of metal-on-metal. substrates. Physical Review Letters. 65 (6): S. 733.
Yoshimura T., Tatsuura S., Sotoyama W. (1991) Polymer films formed with monolayer growth steps by molecular layer deposition. Applied Physics Letters. 59 (4): 482-484.
Auciello O., Gifford K.D., Kingon A.I. (1994) Control of structure and electrical properties of lead-zirconium-titanate-based ferroelectric capacitors produced using a layer-by-layer ion beam sputter-deposition technique. Applied Physics Letters. 64 (21): 2873-2875.
Matsuura T., Murota J., Sawada Y. et al. (1993) Self-limited layer-by-layer etching of Si by alternated chlorine adsorption and Ar ion irradiation. Applied Physics Letters. 63 (20): 2803-2805.
Ferreira M., Rubner M.F. (1995) Molecular-level processing of conjugated polymers. 1. Layer-by-layer manipulation of conjugated polyions. Macromolecules. 28 (21): 7107-7114.
Seki T., Sakuragi M., Kawanishi Y. et al. (1993) Command surfaces of Langmuir-Blodgett films. Photoregulations of liquid crystal alignment by molecularly tailored surface azobenzene layers. Langmuir. 9 (1): 211-218.
Schmitt J., Gruenewald T., Decher G. et al. (1993) Internal structure of layer-by-layer adsorbed polyelectrolyte films: a neutron and X-ray reflectivity study. Macromolecules. 26 (25): 7058-7063.
Gradov O.V., Jablokov A.G. (2016) Novel morphometrics-on-a-chip: CCD- or CMOS-lab-on-a-chip based on discrete converters of different physical and chemical parameters of histological samples into the optical signals with positional sensitivity for morphometry of non-optical patterns. Journal of Biomedical Technologies. 2: 1-29.
Gradov O.V. (2017) Multi-functional microprobe lab-on-a-chip based on the active-pixel sensor with the position-sensitive cassette masks assembled from discrete converters of different biophysical and biochemical parameters into the optical response signals. International Journal of Modern Physics. 1: 23-28.
Yang J.K.W., Jung Y.S., Chang J.B. et al. (2010) Complex self-assembled patterns using sparse commensurate templates with locally varying motifs. Nature Nanotechnology. 5: 256-260.
Smits E.C.P., Mathijssen S.G.J., van Hal P.A. et al. (2008) Bottom-up organic integrated circuits. Nature. 455 (7215): 956-959.
Chang J.-B., Choi H.K., Hannon A.F. et al. (2014). Design rules for self-assembled block copolymer patterns using tiled templates. Nature Communications. 5: 3305.
Bita I., Yang J.K., Jung Y.S. et al. (2008) Graphoepitaxy of self-assembled block copolymers on two-dimensional periodic patterned templates. Science. 321 (5891): 939-943.
Jung Y.S., Chang J.B., Verploegen E. et al. (2010) A path to ultranarrow patterns using self-assembled lithography. Nano Letters. 10 (3): 1000-1005.
Trumler W., Schlingmann S., Ungerer T. et al. (2008) Self-optimized Routing in a Network on-a-Chip. In: Biologically-Inspired Collaborative Computing. B., Springer: 199-212.
Collet J.H., Zajac P., Psarakis M. et al. (2011) Chip self-organizati and fault tolerance in massively defecti e multi ore arrays. IEEE Transacti on Dependable and Secure Computi. 8 (2): 207-217.
Feklichev V.G. (1966) Microcrystallomorphological analysis, Moscow: Science, 200 p.
Feklichev V.G. (1970) Microcrystallomorphological research, Moscow: Science, 176 p.
Keywords:
additive technologies, lab-on-a-chip manufacturing, layer-by-layer growth, conservative self-organization, soft matter mesofluidic chips, dissipative self-assembly.
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