Current Status and Future Trends of Nanoscale Technology and Its Impact on Modern Computing, Biology, Medicine and Agricultural Biotechnology

Nanoscale technologies have gone from being just an ambitious concept to being a rapidly advancing area of interdisciplinary science with immense practical importance. Feynman's vision on nanoscience provided great impetus to the development of nanophysics, nanochemistry, nanoelectronics and na...

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Hauptverfasser:	Majumder, D. Dutta, Ulrichs, Christian, Majumder, Debosmita, Mewis, Inga, Thakur, Ashoke Ranjan, Brahmachary, R.L., Banerjee, Rajat, Rahman, Ayesha, Debnath, Nitai, Seth, Dipankar, Das, Sumistha, Roy, Indrani, Ghosh, Amrita, Sagar, Prity, Schulz, Carsten, Linh, Nguyen Quang, Goswami, Arunava
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Agriculture Alzheimer's disease Atomic force microscopy Biology computing Biotechnology cancer computational biology Computational intelligence consciousness cybernetics genomics HIV Humans hydrophobic nanosilica lipophilic nanosilica machine learning malaria metabolomics Nanobioscience Nanoelectronics Nanoscale devices Nanoscience nanosilica neuronal network pervasive computing quantum mechanics reversible computing Scanning electron microscopy Transmission electron microscopy
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creator	Majumder, D. Dutta Ulrichs, Christian Majumder, Debosmita Mewis, Inga Thakur, Ashoke Ranjan Brahmachary, R.L. Banerjee, Rajat Rahman, Ayesha Debnath, Nitai Seth, Dipankar Das, Sumistha Roy, Indrani Ghosh, Amrita Sagar, Prity Schulz, Carsten Linh, Nguyen Quang Goswami, Arunava
description	Nanoscale technologies have gone from being just an ambitious concept to being a rapidly advancing area of interdisciplinary science with immense practical importance. Feynman's vision on nanoscience provided great impetus to the development of nanophysics, nanochemistry, nanoelectronics and nanotechnology in general. High resolution microscopic devices such as scanning tunneling microscope, transmission electron microscope and atomic force microscope etc. in mid 1980s allowed researchers to see individual atoms on surfaces and arrange them. The authors (nanobiologists, computer scientists, biotechnologists and material scientists) attempt to provide a review of the state of the art in the field of nanoscale technologies and its impact on various fields of research like computation, basic biology, medicine and agricultural biotechnology. Imprints of memory mechanisms in living systems operating at different levels (e.g. biochemical, immunological and neuronal) have provided inputs to design and fabricate 'bio-inspired' nanoelectronic devices suitable for various applications. Several examples of such nanoscale technology based frameworks and devices are presented in the scenario of their potential role in the development of future nanoscale technologies. Nanoscale technologies might finally revolutionize computational intelligence and thinking. The power and limits of computing processes govern the intelligence, knowledge acquisition and thinking process of human and machine. Present computational methods and models provide us courage to study the problem, but these tools are not yet sufficient to answer the following riddles of machine intelligence - what can computers do better than humans? What can humans do better than computers? And the most important one - what is computable? The authors try to present evidences that show bio-inspired nanoscale technologies might gain the power in helping us to go deeper into these challenges of research in future
doi_str_mv	10.1109/ICCTA.2007.46
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Dutta ; Ulrichs, Christian ; Majumder, Debosmita ; Mewis, Inga ; Thakur, Ashoke Ranjan ; Brahmachary, R.L. ; Banerjee, Rajat ; Rahman, Ayesha ; Debnath, Nitai ; Seth, Dipankar ; Das, Sumistha ; Roy, Indrani ; Ghosh, Amrita ; Sagar, Prity ; Schulz, Carsten ; Linh, Nguyen Quang ; Goswami, Arunava</creator><creatorcontrib>Majumder, D. Dutta ; Ulrichs, Christian ; Majumder, Debosmita ; Mewis, Inga ; Thakur, Ashoke Ranjan ; Brahmachary, R.L. ; Banerjee, Rajat ; Rahman, Ayesha ; Debnath, Nitai ; Seth, Dipankar ; Das, Sumistha ; Roy, Indrani ; Ghosh, Amrita ; Sagar, Prity ; Schulz, Carsten ; Linh, Nguyen Quang ; Goswami, Arunava</creatorcontrib><description>Nanoscale technologies have gone from being just an ambitious concept to being a rapidly advancing area of interdisciplinary science with immense practical importance. Feynman's vision on nanoscience provided great impetus to the development of nanophysics, nanochemistry, nanoelectronics and nanotechnology in general. 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Several examples of such nanoscale technology based frameworks and devices are presented in the scenario of their potential role in the development of future nanoscale technologies. Nanoscale technologies might finally revolutionize computational intelligence and thinking. The power and limits of computing processes govern the intelligence, knowledge acquisition and thinking process of human and machine. Present computational methods and models provide us courage to study the problem, but these tools are not yet sufficient to answer the following riddles of machine intelligence - what can computers do better than humans? What can humans do better than computers? And the most important one - what is computable? The authors try to present evidences that show bio-inspired nanoscale technologies might gain the power in helping us to go deeper into these challenges of research in future</abstract><pub>IEEE</pub><doi>10.1109/ICCTA.2007.46</doi><tpages>11</tpages></addata></record>
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subjects	Agriculture Alzheimer's disease Atomic force microscopy Biology computing Biotechnology cancer computational biology Computational intelligence consciousness cybernetics genomics HIV Humans hydrophobic nanosilica lipophilic nanosilica machine learning malaria metabolomics Nanobioscience Nanoelectronics Nanoscale devices Nanoscience nanosilica neuronal network pervasive computing quantum mechanics reversible computing Scanning electron microscopy Transmission electron microscopy
title	Current Status and Future Trends of Nanoscale Technology and Its Impact on Modern Computing, Biology, Medicine and Agricultural Biotechnology
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