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9783030996000
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10.1007/978-3-030-99600-0
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doi
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(DE-He213)978-3-030-99600-0
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TA401-492
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Flexible Sensors for Energy-Harvesting Applications
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[electronic resource] /
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edited by Anindya Nag, Subhas Chandra Mukhopadhyay.
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1st ed. 2022.
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Cham :
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Springer International Publishing :
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Imprint: Springer,
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2022.
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1 online resource (VIII, 238 p.) 83 illus., 80 illus. in color.
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text
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txt
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rdacontent
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computer
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rdamedia
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online resource
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cr
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rdacarrier
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text file
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PDF
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rda
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Smart Sensors, Measurement and Instrumentation,
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2194-8410 ;
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42
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Introduction -- Need of flexible sensors in the sensing world -- Impact of nanotechnology of the quality of the flexible sensors -- Fabrication and implementation of nanomaterials-assisted flexible sensors -- Fabrication and implementation of nanomaterials-assisted flexible sensors -- Flexible piezoelectric and triboelectric sensors for energy harvesting applications -- Flexible piezoelectric and triboelectric sensors for energy harvesting applications -- Flexible piezoelectric and triboelectric sensors for energy harvesting applications -- Flexible piezoelectric and triboelectric sensors for energy harvesting applications -- Flexible piezoelectric and triboelectric sensors for energy harvesting applications -- Conclusion and future opportunities.
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Access restricted by licensing agreement.
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This book investigates the fabrication of different types of flexible sensors and their subsequent implementation for energy-harvesting applications. A range of techniques, including 3D printing, soft lithography, laser ablation, micro-contract printing, screen-printing, inkjet printing and others have been used to form the flexible sensors with varied characteristics. These sensors have been used for biomedical, environmental and healthcare applications on the basis of their performances. The quality of these flexible sensors has depended on certain types of nanomaterials that have been used to synthesize the conductive parts of the prototypes. These nanomaterials have been based on different sizes and shapes, whose quality varied on the basis of certain factors like crystallinity, shapes and sizes. One of the primary utilization of these nanotechnology-based flexible sensors has been the harvesting of energy where nano-generators and nano-harvesters have been formed to generate and store energy, respectively, on small and moderate magnitudes. Mechanical and thermal energies have been harvested on the basis of the piezoelectric, pyroelectric and triboelectric effects created by the formed prototypes. The work highlights the amalgamation of these sectors to spotlight the essence of these types of sensors and their intended application. .
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Access is available to the Yale community.
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Materials.
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Detectors.
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Measurement.
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Measuring instruments.
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Energy harvesting.
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Nag, Anindya.
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editor.
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edt
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http://id.loc.gov/vocabulary/relators/edt
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Mukhopadhyay, Subhas Chandra.
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editor.
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edt
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http://id.loc.gov/vocabulary/relators/edt
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SpringerLink (Online service)
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Springer ENIN.
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Springer Nature eBook
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8
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Printed edition:
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9783030995997
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Printed edition:
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9783030996017
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Printed edition:
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9783030996024
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Smart Sensors, Measurement and Instrumentation,
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2194-8410 ;
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42
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0
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yulint
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None
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Online resource
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0
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Online resource
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Online book
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https://yale.idm.oclc.org/login?URL=https://doi.org/10.1007/978-3-030-99600-0
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TA401-492
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Yale Internet Resource
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Yale Internet Resource >> None|DELIM|16146149
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online resource
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2022-04-22T14:08:22.000Z
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DO NOT EDIT. DO NOT EXPORT.
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https://doi.org/10.1007/978-3-030-99600-0