Nanomaterials : : Volume 1: Electronic Properties / / Engg Kamakhya Prasad Ghatak, Madhuchhanda Mitra.
The work studies under different physical conditions the carrier contribution to elastic constants in heavily doped optoelectronic materials. In the presence of intense photon field the authors apply the Heisenberg Uncertainty Principle to formulate electron statistics. Many open research problems a...
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Superior document: | Title is part of eBook package: De Gruyter DG Plus eBook-Package 2019 |
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Place / Publishing House: | Berlin ;, Boston : : De Gruyter, , [2018] ©2019 |
Year of Publication: | 2018 |
Language: | English |
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Physical Description: | 1 online resource (XLII, 364 p.) |
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Table of Contents:
- Frontmatter
- Preface
- Acknowledgments
- Contents
- About the Authors
- Symbols
- 1. Heisenberg’s uncertainty principle (HUP) and the carrier contribution to the elastic constants in heavily doped (HD) optoelectronic nanomaterials in the presence of intense light waves
- 2. Heisenberg’s uncertainty principle and Einstein’s photoemission from HD optoelectronic nanomaterials in the presence of intense light waves
- 3. The Heisenberg’s uncertainty principle and the diffusivity to mobility ratio from HD optoelectronic nanomaterials in the presence of intense light waves
- 4. Heisenberg’s uncertainty principle and the screening length in heavily doped optoelectronic nano materials in the presence of intense light waves
- 5. Heisenberg’s uncertainty principle and field emission in optoelectronic nanomaterials
- 6. Conclusion and scope for future research
- Appendix: The numerical values of the energy band constants of few materials
- Materials Index
- Subject Index