1. |
Grigoryan N., Chudziński P., Low energy field electron emission from nanostructures: theoretical framework,
MAOP 2024, International College on Modern Applications of Optics and Photonics 2024, 2024-08-12/08-23, Yerevaw (AM), pp.33, 2024 | |
2. |
Grigoryan N., Chudziński P., Effective Tomonaga-Luttinger liquid theory for multi-wall nanotubes,
KonDokPAN 2024, VIII Konferencja Doktorantów PAN, 2024-10-11/10-13, WARSZAWA (PL), pp.29, 2024 | |
3. |
Grigoryan N., Chudziński P., Multiscale Field Emission Theory for Composite Surfaces with Strong Electron-Electron Interactions,
SolMech 2024, 43rd Solid Mechanics Conference, 2024-09-16/09-18, Wrocław (PL), pp.1, 2024 | |
4. |
Grigoryan N., Chudziński P., Generalizing Field Emission Theory for Surfaces with Strong Electron-Electron Interactions,
2nd International Virtual Conference on Materials Science and Engineering, 2023-11-11/11-12, Londyn (GB), pp.1-1, 2023 | |
5. |
Grigoryan N., Chudziński P., The role of electron-electron interactions in electron emission from nanotube materials,
KonDokPAN 2023, 7th Conference of Doctoral Students of the PAS, 2023-10-13/10-15, Wrocław (PL), pp.1-1, 2023 | |
6. |
Grigoryan N., Chudziński P., The role of electron-electron interactions in electron emission from arrays of nanotubes,
SKM2023, DPG Spring Meeting of the Condensed Matter Section , 2023-03-26/03-31, Drezno (DE), No.1, pp.1-1, 2023Abstract: Nanotubes and nanorods have been recently established as very good materials to build electron sources in the cold emission process. These are 1D materials where electron-electron interactions are known to play a crucial role in their physics. The interactions in 1D systems lead to a collective modes’ physics that is usually described using Tomonaga-Luttinger liquid (TLL) formalism. The advantage is that within thismethod all correlation functions are known and can be expressed interms of power laws with non-universal, interaction dependent, ex-ponents. To capture this situation we generalize a canonical Fowler-Northeim theory of field emission to solve the case of a barrier described by any power-law potential. With this generalization, expressed in terms of a confluent hypergeometric function, we are able to compute currents from arrays of carbon nanotubes. We shall present results showing an influence of various interaction terms, as encoded in varying TLL parameters, as well as effects of a finite temperature. Affiliations:
Grigoryan N. | - | IPPT PAN | Chudziński P. | - | IPPT PAN |
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7. |
Grigoryan N., Fourier modal method analysis of light interactions with binary dielectric gratings,
IONS Yerevan, 2018-08-30/09-02, Yerevan (AM), pp.1, 2018 | |