Physical Review

Physical Review is a peer-reviewed scientific journal established in 1893 by Edward Nichols. It publishes original research as well as scientific and literature reviews on all aspects of physics. It is published by the American Physical Society (APS). The journal is in its third series, and is split in several sub-journals each covering a particular field of physics. It has a sister journal, Physical Review Letters, which publishes shorter articles of broader interest. History Physical Review commenced publication in July 1893, organized by Cornell University professor Edward Nichols and helped by the new president of Cornell, J. Gould Schurman. The journal was managed and edited at Cornell in upstate New York from 1893 to 1913 by Nichols, Ernest Merritt, and Frederick Bedell. The 33 volumes published during this time constitute Physical Review Series I. The American Physical Society (APS), founded in 1899, took over its publication in 1913 and started Physical Review

About this result

This page is automatically generated and may contain information that is not correct, complete, up-to-date, or relevant to your search query. The same applies to every other page on this website. Please make sure to verify the information with EPFL's official sources.

Related publications

Related people

Related units

Related concepts

Related courses

Related lectures

Summary

Official source

About this result

Related publications (12)

Related publications

Related people

Related units

Related concepts (41)

Related concepts

Related courses (29)

Related courses

Related lectures (45)

Related lectures

Charge transport mechanisms in organic and microcrystalline silicon field-effect transistors

Marie-Noëlle Bussac, Steven Konezny, Libero Zuppiroli

Several organic and inorganic materials have emerged as promising candidates for the active layer of field-effect transistors (FETs) fabricated on flexible substrates. The charge transport models necessary for device optimization in these systems are at different stages of development. The understanding of charge transport in single-crystal and thin-film FETs based on organic materials such as pentacene, rubrene, and other related compounds has advanced considerably in recent years and a clear picture of the relevant transport mechanisms is forming. In contrast, the theoretical description of transport in hydrogenated microcrystalline silicon (µc-Si:H) is not as well known and the published results and theories are often contradictory. We review the paradigms we feel are useful in describing the current understanding of transport in organic and µc-Si:H field-effect transistors. In the case of organic materials these include the polarization and transfer integral fluctuation model [A. Troisi and G. Orlandi, Phys. Rev. Lett. 96, 086601 (2006), J.-D. Picon et al., Phys. Rev. B 75, 235106 (2007)], the Frlich polaron model [I.N. Hulea et al., Nat. Mater. 5, 982 (2006), H. Houilli et al., J. Appl. Phys. 100, 033702 (2006)], and several trapping models [M.E. Gershenson et al., Rev. Mod. Phys. 78, 973 (2006), V. Podzorov et al., Phys Rev. Lett. 95, 226601 (2005)]. Given the heterogeneous composition and structure of microcrystalline silicon thin films, a variety of theories to describe dark conductivity have been applied to µc-Si:H including those based on percolation theory [H. Overhof et al., J. Non-Cryst. Solids 227-230, 992 (1998)], hopping models [A. Dussan and R. H. Buitrago, J. Appl. Phys. 97, 043711 (2005)], thermionic emission, and tunneling. We give a brief overview of these models and present a fluctuation-induced tunneling model that we are developing to describe charge transport in microcrystalline silicon.

International Society for Optical Engineering, Bellingham WA, WA 98227-0010, United States2007

Charge transport mechanisms in organic and microcrystalline silicon field-effect transistors

Marie-Noëlle Bussac, Steven Konezny, Libero Zuppiroli

Several organic and inorganic materials have emerged as promising candidates for the active layer of field-effect transistors (FETs) fabricated on flexible substrates. The charge transport models necessary for device optimization in these systems are at different stages of development. The understanding of charge transport in single-crystal and thin-film FETs based on organic materials such as pentacene, rubrene, and other related compounds has advanced considerably in recent years and a clear picture of the relevant transport mechanisms is forming. In contrast, the theoretical description of transport in hydrogenated microcrystalline silicon (mu c-Si:H) is not as well known and the published results and theories are often contradictory. We review the paradigms we feel are useful in describing the cur-rent understanding of transport in organic and mu c-Si:H field-effect transistors. In the case of organic materials these include the polarization and transfer integral fluctuation model [A. Troisi and G. Orlandi, Phys. Rev. Lett. 96, 086601 (2006), J.-D. Picon et al., Phys. Rev. B 75, 235106 (2007)], the Frolich polaron model [I.N. Hulea el al., Nat. Mater. 5, 982 (2006), H. Houilli et al., J. Appl. Phys. 100, 033702 (2006)], and several trapping models [M.E. Gershenson et al., Rev. Mod. Phys. 78, 973 (2006), V. Podzorov et al., Phys Rev. Lett. 95, 226601 (2005)]. Given the heterogeneous composition and structure of microcrystalline silicon thin films, a variety of theories to describe dark conductivity have been applied to mu c-Si:H including those based on percolation theory [H. Overhof et al., J. Non-Cryst. Solids 227-230, 992 (1998)], hopping models [A. Dussan and R. H. Buitrago, J. Appl. Phys. 97, 043711 (2005)], thermionic emission, and tunneling. We give a brief overview of these models and present a fluctuation-induced tunneling model that we are developing to describe charge transport in microcrystalline silicon.

Spie-Int Soc Optical Engineering, Po Box 10, Bellingham, Wa 98227-0010 Usa2007

Acoustic Topological Fano Resonances

Romain Christophe Rémy Fleury, Farzad Zangeneh Nejad

Originally discovered in the context of quantum mechanics in 1961, the ultra-sharp spectrum of the Fano resonance has nowadays established itself as centerpiece in modern engineering for realizing a large variety of prominent devices including low energy switches [1], efficient sources and emitters [2], and highly sensitive interferometers [3]. In addition, the peculiar asymmetric line shape of the Fano resonance is found to be substantially sensitive to environmental changes, establishing a unique platform for the implementation of highly sensitive sensors and actuators [4]. The excessive sensitivity of the Fano resonance to environmental and structural parameters is, however, not always desirable as it makes the practical implementation of Fano structures extremely challenging, mitigating the performance advantages obtained from Fano interference by costs related to the fabrication technology. Here, we report our recent theoretical findings and experimental observations of acoustic topological Fano resonances whose much-sought line-shapes is guaranteed by topology, offering a unique protection against geometrical tolerances. We construct such topological Fano resonances from interaction between a bright and a dark mode that both have topological origin, and demonstrate this concept experimentally for audible airborne sound in a one-dimensional acoustic scenario. By going beyond the performance degradation caused by inadvertent fabrication flaws, such protection paves the way for a new generation of Fano-based acoustic devices which, not only possess exotic properties as any other Fano structure, but also can be readily implemented in practice with very low cost [5]. 1. K. Nozaki, et al. Optics express 21.10 (2013): 11877-11888. 2. S. Chua, et al. Optics express 19.2 (2011): 1539-1562. 3. K. Heeg, et al. Physical review letters 114.20 (2015): 207401. 4. C. Wu, et al. Nature materials 11.1 (2012): 69. 5. F. Zangeneh-Nejad, and R. Fleury, Physical review letters. 122 (2019): 014301

2019

Physics

Physics is the natural science of matter, involving the study of matter, its fundamental constituents, its motion and behavior through space and time, and the related entities of energy and force. Phy

Quantum mechanics

Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quan

Particle physics

Particle physics or high energy physics is the study of fundamental particles and forces that constitute matter and radiation. The fundamental particles in the universe are classified in the Standard

PHYS-420: Solid state physics IV

Solid State Physics IV provides a materials and experimental technique oriented introduction to the electronic and magnetic properties of strongly correlated electron systems. Established knowledge is complemented by current research trends, aiming to prepare the students for independent research.

PHYS-637: Electron Matter Interactions in Transmission Electron Microscopy

This course will present the fundamentals of electronâmatter interactions, as occuring in the energy range available in modern transmission electron microscopes, namely 60-300 keV electrons. Diffraction and high-resolution image formation as well as electron energy-loss spectrometry will be covere

EE-201: Electromagnetics II : field computation

Ce cours traite de l'électromagnétisme dans le vide et dans les milieux continus. A partir des principes fondamentaux de l'électromagnétisme, on établit les méthodes de résolution des équations de Maxwell dans le vide et dans des milieux matériels complexes.