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Books on the topic 'Semiconducting Nanostructures'

Author: Grafiati
Published: 7 September 2023

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1

Banerjee, Arghya N. P-type transparent semiconducting delafossite cualo2+x thin film. New York: Nova Science Publishers, 2008.

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2

Sharma, Surbhi, Neeraj Khare, and Mohd Faraz. Advances in Semiconducting Nanostructures for Photoelectrochemical Water Splitting. Elsevier Science & Technology, 2023.

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3

Sharma, Surbhi, Neeraj Khare, and Mohd Faraz. Advances in Semiconducting Nanostructures for Photoelectrochemical Water Splitting. Elsevier Science & Technology, 2023.

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4

Kong, X. Y., Y. C. Wang, X. F. Fan, G. F. Guo, and L. M. Tong. Free-standing grid-like nanostructures assembled into 3D open architectures for photovoltaic devices. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533060.013.22.

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This article describes three-dimensional open architectures with free-standing grid-like nanostructure arrays as photocatalytic electrodes for a new type of dye-sensitized solar cell. It introduces a novel technique for fabricating a series of semiconducting oxides with grid-like nanostructures replicated from the biotemplates. These semiconducting oxides, including n-type titanium dioxide or p-type nickel oxide nanogrids, were sensitized with the dye molecules, then assembled into 3D stacked-grid arrays on a flexible substrate by means of the Langmuir–Blodgett method or the ink-jet printing technique for the photocatalytic electrodes. The article first considers the fabrication of photoelectrodes with 2D grid-like nanostructures by means of the biotemplating approach before discussing the assembly and photophysicsof grid-like nanostructures into 3D open architectures for the photocatalytic electrodes.
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5

Tuning Semiconducting and Metallic Nanostructures: Spectroscopy, Dynamics, and Self-Assembly. Taylor & Francis Group, 2016.

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6

Kumar, A. 1D Semiconducting Hybrid Nanostructures -Synthesis and Applications in Gas Sensing AndOptoelectronics. Wiley & Sons, Limited, John, 2022.

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7

Aswal, Dinesh K., Arvind Kumar, and Nirav Joshi. 1D Semiconducting Hybrid Nanostructures: Synthesis and Applications in Gas Sensing and Optoelectronics. Wiley & Sons, Incorporated, John, 2023.

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8

Aswal, Dinesh K., Arvind Kumar, and Nirav Joshi. 1D Semiconducting Hybrid Nanostructures: Synthesis and Applications in Gas Sensing and Optoelectronics. Wiley & Sons, Incorporated, John, 2023.

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9

Aswal, Dinesh K., Arvind Kumar, and Nirav Joshi. 1D Semiconducting Hybrid Nanostructures: Synthesis and Applications in Gas Sensing and Optoelectronics. Wiley & Sons, Limited, John, 2022.

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10

Ahmad, Muhammad, Ravinder Dahiya, Dhayalan Shakthivel, Mohammad R. Alenezi, and S. Ravi P. Silva. 1D Semiconducting Nanostructures for Flexible and Large-Area Electronics: Growth Mechanisms and Suitability. Cambridge University Press, 2019.

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11

Ahmad, Muhammad, Ravinder Dahiya, Dhayalan Shakthivel, Mohammad R. Alenezi, and S. Ravi P. Silva. 1D Semiconducting Nanostructures for Flexible and Large-Area Electronics: Growth Mechanisms and Suitability. Cambridge University Press, 2019.

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12

Yousefi, Ramin. Optical Properties of Semiconducting Nanostructures for Photocatalytic Applications: Fundamental Understanding and Material Design. Elsevier Science & Technology, 2021.

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13

Hayazawa, Norihiko, and Prabhat Verma. Nanoanalysis of materials using near-field Raman spectroscopy. Edited by A. V. Narlikar and Y. Y. Fu. Oxford University Press, 2017. http://dx.doi.org/10.1093/oxfordhb/9780199533053.013.10.

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This article describes the use of tip-enhanced near-field Raman spectroscopy for the characterization of materials at the nanoscale. Tip-enhanced near-field Raman spectroscopy utilizes a metal-coated sharp tip and is based on surface-enhanced Raman scattering (SERS). Instead of the large surface enhancement from the metallic surface in SERS, the sharp metal coated tip in the tip-enhanced Raman scattering (TERS) provides nanoscaled surface enhancement only from the sample molecules in the close vicinity of the tip-apex, making it a perfect technique for nanoanalysis of materials. This article focuses on near-field analysis of some semiconducting nanomaterials and some carbon nanostructures. It first considers SERS analysis of strained silicon and TERS analysis of epsilon-Si and GaN thin layers before explaining how to improve TERS sensitivity and control the polarization in detection for crystalline materials. It also discusses ways of improving the spatial resolution in TERS.
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14

Coffer, J. L. Semiconducting Silicon Nanowires for Biomedical Applications. Elsevier Science & Technology, 2021.

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15

Coffer, J. L. Semiconducting Silicon Nanowires for Biomedical Applications. Elsevier Science & Technology, 2014.

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16

Coffer, J. L. Semiconducting Silicon Nanowires for Biomedical Applications. Elsevier Science & Technology, 2014.

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17

Wang, Bing, Han Zhang, and Nasir Mahmood Abbasi. Semiconducting Black Phosphorus. Taylor & Francis Group, 2021.

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18

Semiconducting Silicon Nanowires for Biomedical Applications. Elsevier Science & Technology, 2014.

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19

Wang, Bing, Han Zhang, and Nasir Mahmood Abbasi. Semiconducting Black Phosphorus: From 2D Nanomaterial to Emerging 3D Architecture. Taylor & Francis Group, 2021.

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20

Wang, Bing, Han Zhang, and Nasir Mahmood Abbasi. Semiconducting Black Phosphorus: From 2D Nanomaterial to Emerging 3D Architecture. CRC Press LLC, 2021.

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21

Semiconducting Black Phosphorus: From 2D Nanomaterial to Emerging 3D Architecture. Taylor & Francis Group, 2021.

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22

Wang, Bing, Han Zhang, and Nasir Mahmood Abbasi. Semiconducting Black Phosphorus: From 2D Nanomaterial to Emerging 3D Architecture. Taylor & Francis Group, 2021.

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23

Panigrahi, Muktikanta, and Arpan Kumar Nayak. Polyaniline based Composite for Gas Sensors. IOR PRESS, 2021. http://dx.doi.org/10.34256/ioriip212.

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In this research work, we have demonstrated the synthesis, spectroscopic characteristics, thermal behaviour and DC conductivity of a few nanostructured composites, substituted conducting polymers (ICPs) and composites of ICPs. The physical properties of aforementioned composites are significantly changed by the doping with HCl, H2SO4, HNO3, H3PO4, or acrylic acid. The charge transport properties of these polymeric materials have been studied in detail because of their potential application in gas sensors. In the current work, varieties of conducting polymer based materials such as PANI-ES/Cloisite 20A nanostructured composite, acrylic acid (AA) doped PANI polymer, N-substituted conducting polyaniline polymer, DL−PLA/PANI-ES composites, poly methyl methacrylate (PMMA) based polyaniline composite, and inorganic acid doped polyaniline are sucessfuly synthesized using aniline/aniline hydrochloride as precursors in acidic medium. Particularly, AA based synthesised PANI polymer was found with higher solubility The spectroscopic, thermal stability, enthalpy of fusion, room temperature DC conductivity and temperature dependent DC conductivity measurements with and without magnetic was carried out with as-synthesized materials. The FTR/ATR−FTIR spectra indicated the presence of different functional groups in the as-prepared composite materials. The UV−Visible absorption spectroscopic analysis showed the presence of polaron band suggesting PANI-ES form. The Room temperature DC conductivity, temperature variation DC conductivity (in presence and absence of magnetic field), and magnetoresistance (MR) of as-prepared conducting polyaniline based were analysed. The highest room temperature DC conductivity value was obtained from H2SO4 doped based composite materials and all prepared conductive composites were followed ohms law. The low temperature DC conductivity was carried out in order to study the semiconducting nature of prepared materials. The Mott type VRH model was found to be well fitted the conductivity data and described the density of states at the Fermi level which is constant in this temperature range. From MR plots, a negative MR was observed, which described the quantum interference effect on hopping conduction. We discuss different gas analytes i.e., NO2, LPG, H2, NH3, CH4, and CO of conducting polymer based materials.
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