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Books on the topic 'Molecular self-Assembly of insulating'

Author: Grafiati
Published: 4 June 2021
Last updated: 25 May 2024

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1

R, Nagarajan. Amphiphiles: Molecular assembly and applications. Washington, DC: American Chemical Society, 2011.

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2

Fuiita, Makoto, ed. Molecular Self-Assembly Organic Versus Inorganic Approaches. Berlin, Heidelberg: Springer Berlin Heidelberg, 2000. http://dx.doi.org/10.1007/3-540-46591-x.

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3

service), ScienceDirect (Online, ed. Systems self-assembly: Multidisciplinary snapshots. Amsterdam: Elsevier Science, 2008.

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4

Frederic, Fages, and Araki K, eds. Low molecular mass gelators: Design, self-assembly, function. Berlin: Springer, 2005.

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5

Frédéric, Fages, and Araki K, eds. Low molecular mass gelators: Design, self-assembly, function. Berlin: Springer, 2005.

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6

Comrie, James P., and James P. Comrie. Molecular self-assembly: Advances in chemistry, biology, and nanotechnology. Hauppauge, N.Y: Nova Science Publishers, 2010.

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7

Comrie, James P. Molecular self-assembly: Advances in chemistry, biology, and nanotechnology. Hauppauge, N.Y: Nova Science Publishers, 2010.

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8

Pierandrea, Lo Nostro, ed. Molecular forces and self assembly: In colloid, nano sciences and biology. Cambridge: Cambridge University Press, 2010.

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9

Claessens, Christian Georges. Self-assembly and self-organisation of molecular compounds containing complementary [pi]-[pi] interacting units. Birmingham: University of Birmingham, 1997.

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10

M, Rotello Vincent, and Thayumanavan Sankaran, eds. Molecular recognition and polymers: Control of polymer structure and self-assembly. Hoboken, N.J: Wiley, 2008.

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11

Gómez-López, Marcos. The self-assembly of novel molecular compounds and their potential device-like properties. Birmingham: University of Birmingham, 1997.

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12

Liquid crystals: Materials design and self-assembly. Heidelberg: Springer, 2012.

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13

Chiechi, Ryan, Jane Kardula, and Rachael Hannah. Molecular Electronics: Monolayers and Self-Assembly. de Gruyter GmbH, Walter, 2023.

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14

Gazit, Ehud, and Saul Tendler. Molecular Self-Assembly for Biomaterials Design. Royal Society of Chemistry, The, 2019.

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15

Chiechi, Ryan, Jane Kardula, and Rachael Hannah. Molecular Electronics: Monolayers and Self-Assembly. de Gruyter GmbH, Walter, 2023.

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16

Dequan, Alex Li. Molecular Self-Assembly: Advances and Applications. Jenny Stanford Publishing, 2012.

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17

Molecular Self-Assembly: Advances and Applications. Taylor & Francis Group, 2012.

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18

Dequan, Alex Li. Molecular Self-Assembly: Advances and Applications. Jenny Stanford Publishing, 2012.

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19

Chiechi, Ryan, Jane Kardula, and Rachael Hannah. Molecular Electronics: Monolayers and Self-Assembly. de Gruyter GmbH, Walter, 2023.

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20

Kilislioğlu, Ayben, and Selcan Karakuş, eds. Molecular Self-assembly in Nanoscience and Nanotechnology. InTech, 2017. http://dx.doi.org/10.5772/65607.

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21

Fujita, Makoto. Molecular Self-Assembly: Organic Versus Inorganic Approaches. Springer London, Limited, 2003.

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22

Fujita, Makoto. Molecular Self-Assembly: Organic Versus Inorganic Approaches. Springer, 2013.

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23

Molecular Self-Assembly: Organic Versus Inorganic Approaches. Springer, 2000.

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24

Krasnogor, Natalio, David A. Pelta, Steve Gustafson, and Jose L. Verdegay. Systems Self-Assembly: Multidisciplinary Snapshots. Elsevier Science & Technology Books, 2011.

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25

Fages, Frederic. Low Molecular Mass Gelators: Design, Self-Assembly, Function. Springer Berlin / Heidelberg, 2010.

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26

Ninham, Barry W., and Pierandrea Lo Nostro. Molecular Forces and Self Assembly: In Colloid, Nano Sciences and Biology. Cambridge University Press, 2010.

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27

Ninham, Barry W., and Pierandrea Lo Nostro. Molecular Forces and Self Assembly: In Colloid, Nano Sciences and Biology. Cambridge University Press, 2010.

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28

Ninham, Barry W., and Pierandrea Lo Nostro. Molecular Forces and Self Assembly: In Colloid, Nano Sciences and Biology. Cambridge University Press, 2010.

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29

Rotello, Vincent, and Sankaran Thayumanavan. Molecular Recognition and Polymers: Control of Polymer Structure and Self-Assembly. Wiley & Sons, Incorporated, John, 2008.

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30

Tschierske, Carsten. Liquid Crystals: Materials Design and Self-assembly. Springer, 2014.

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31

Lindoy, L. F., and I. M. Atkinson. Self-Assembly in Supramolecular Systems (Monographs in Supramolecular Chemistry). Royal Society of Chemistry, 2001.

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32

Vvedensky, Dimitri D. Quantum dots: Self-organized and self-limiting assembly. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.6.

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This article describes the self-organized and self-limiting assembly of quantum dots, with particular emphasis on III–V semiconductor quantum dots. It begins with a background on the second industrial revolution, highlighted by advances in information technology and which paved the way for the era of ‘quantum nanostructures’. It then considers the science and technology of quantum dots, followed by a discussion on methods of epitaxial growth and fabrication methodologies of semiconductor quantum dots and other supported nanostructures, including molecular beam epitaxy and metalorganic vapor-phase epitaxy. It also examines self-organization in Stranski–Krastanov systems, site control of quantum dots on patterned substrates, nanophotonics with quantum dots, and arrays of quantum dots.
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33

Carter, Joshua D., Chenxiang Lin, Yan Liu, Hao Yan, and Thomas H. LaBean. DNA-based self-assembly of nanostructures. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.24.

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This article examines the DNA-based self-assembly of nanostructures. It first reviews the development of DNA self-assembly and DNA-directed assembly, focusing on the main strategies and building blocks available in the modern molecular construction toolbox, including the design, construction, and analysis of nanostructures composed entirely of synthetic DNA, as well as origami nanostructures formed from a mixture of synthetic and biological DNA. In particular, it considers the stepwise covalent synthesis of DNA nanomaterials, unmediated assembly of DNA nanomaterials, hierarchical assembly, nucleated assembly, and algorithmic assembly. It then discusses DNA-directed assembly of heteromaterials such as proteins and peptides, gold nanoparticles, and multicomponent nanostructures. It also describes the use of complementary DNA cohesion as 'smart glue' for bringing together covalently linked functional groups, biomolecules, and nanomaterials. Finally, it evaluates the potential future of DNA-based self-assembly for nanoscale manufacturing for applications in medicine, electronics, photonics, and materials science.
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34

Fages, Frederic. Low Molecular Mass Gelators : Design, Self-Assembly, Function (Topics in Current Chemistry) (Topics in Current Chemistry). Springer, 2005.

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35

Hong, S., Y. K. Kwon, J. S. Ha, N. K. Lee, B. Kim, and M. Sung. Self-assembly strategy of nanomanufacturing of hybrid devices. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.10.

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This article considers the nanomanufacturing of hybrid devices using the self-assembly strategy. Hybrid devices utilize nanomaterials such as nanoparticles, organic molecules, carbon nanotubes (CNTs), and nanowires. Examples include CNT-based circuits and molecular electronics. However, a major stumbling block holding back the practical applications of hybrid systems can be a lack of a mass-production method for such devices. This article first describes the direct patterning of nanostructures by means of dip-pen nanolithography and microcontact printing before discussing the fabrication of nanostructures using directed assembly. It also examines the mechanism of various assembly processes ofnanostructures and concludes with an overview of the characteristics of self-assembled hybrid nanodevices.
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36

McGuiness, C. L., R. K. Smith, M. E. Anderson, P. S. Weiss, and D. L. Allara. Nanolithography using molecular films and processing. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.23.

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This article focuses on the use of molecular films as building blocks for nanolithography. More specifically, it reviews efforts aimed at utilizing organic molecular assemblies in overcoming the limitations of lithography, including self-patterning and directed patterning. It considers the methods of patterning self-assembled organic monolayer films through soft-lithographic methods such as microcontact printing and nanoimprint lithography, through direct ‘write’ or ‘machine’ processes with a nanometer-sized tip and through exposure to electron or photon beams. It also discusses efforts to pattern the organic assemblies via the physicochemical self-assembling interactions, including patterning via phase separation of chemically different molecules and insertion of guest adsorbates into host matrices. Furthermore, it examines the efforts that have been made to couple patterned molecular assemblies with inorganic thin-film growth methods to form spatially constrained, three-dimensional thin films. Finally, it describes a hybrid self-assembly/conventional lithography (i.e. molecular rulers) approach to forming nanostructures.
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37

Kirczenow, George. Molecular nanowires and their properties as electrical conductors. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533046.013.4.

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This article describes the properties of molecular nanowires as electrical conductors. It begins by defining a molecular nanowire and describing a specific example of a molecular nanowire, along with the concept of molecular nanowire self-assembly. It then considers how molecular nanowires are realized in the laboratory as well as the relationships between these methodologies, the systems that are produced and some experiments being performed on them. It also looks at the different kinds of molecules, electrodes and linkers out of which molecular nanowires are being or may be constructed; the Landauer approach to electrical conduction in molecular nanowires; the principles and limitations of ab-initio and semi-empirical modelling of molecular nanowires in the context of electrical conduction; and four specific experimental systems and the extent to which their observed behavior has been understood theoretically. The article concludes with a summary of key issues for the future development of the field.
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38

Narlikar, A. V., and Y. Y. Fu, eds. Oxford Handbook of Nanoscience and Technology. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.001.0001.

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This volume highlights engineering and related developments in the field of nanoscience and technology, with a focus on frontal application areas like silicon nanotechnologies, spintronics, quantum dots, carbon nanotubes, and protein-based devices as well as various biomolecular, clinical and medical applications. Topics include: the role of computational sciences in Si nanotechnologies and devices; few-electron quantum-dot spintronics; spintronics with metallic nanowires; Si/SiGe heterostructures in nanoelectronics; nanoionics and its device applications; and molecular electronics based on self-assembled monolayers. The volume also explores the self-assembly strategy of nanomanufacturing of hybrid devices; templated carbon nanotubes and the use of their cavities for nanomaterial synthesis; nanocatalysis; bifunctional nanomaterials for the imaging and treatment of cancer; protein-based nanodevices; bioconjugated quantum dots for tumor molecular imaging and profiling; modulation design of plasmonics for diagnostic and drug screening; theory of hydrogen storage in nanoscale materials; nanolithography using molecular films and processing; and laser applications in nanotechnology. The volume concludes with an analysis of the various risks that arise when using nanomaterials.
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