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Thursday, November 12, 2020 | History

5 edition of Optical spectroscopy of low dimensional semiconductors found in the catalog.

Optical spectroscopy of low dimensional semiconductors

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Published by Kluwer Academic Publishers in Dordrecht, Boston .
Written in English

    Subjects:
  • Low-dimensional semiconductors -- Optical properties -- Congresses,
  • Spectrum analysis -- Congresses

  • Edition Notes

    Statementedited by Gerhard Abstreiter, Atilla Aydinli, Jean-Pierre Leburton.
    SeriesNATO ASI series. Series E, Applied sciences ;, v. 344, NATO ASI series., no. 344.
    ContributionsAbstreiter, Gerhard., Aydinli, Atilla., Leburton, J. P. 1949-, NATO Advanced Study Institute on Optical Spectroscopy of Low Dimensional Semiconductors (1996 : Ankara and Antalya, Turkey)
    Classifications
    LC ClassificationsQC611.6.O6 O6654 1997
    The Physical Object
    Paginationviii, 386 p. :
    Number of Pages386
    ID Numbers
    Open LibraryOL686726M
    ISBN 100792347285
    LC Control Number97033653

      In he joined The Queen's University of Belfast. His current research interests are in the areas of near-field optics, scanning probe microscopy, nanophotonics and plasmonics, nonlinear optics and spectroscopy, surface plasmons and polaritons, and optical properties of surfaces, thin films, semiconductors and low-dimensional structures. Stanford Libraries' official online search tool for books, media, journals, databases, government documents and more.   Raman Spectroscopy and its Application in Nanostructures is an original and timely contribution to a very active area of physics and materials science research. This book presents the theoretical and experimental phenomena of Raman spectroscopy, with specialized discussions on the physical fundamentals, new developments and main features in low Format: Hardcover. @article{osti_, title = {Optical spectroscopy of strongly correlated electron systems}, author = {Schumacher, Andreas B.}, abstractNote = {In this thesis, both time-resolved, nonlinear optical spectroscopy and linear spectroscopy are used to investigate the interactions and dynamics of elementary excitations in strongly correlated electron systems.


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Optical spectroscopy of low dimensional semiconductors Download PDF EPUB FB2

Optical Spectroscopy of Low Dimensional Semiconductors. Editors: Abstreiter, G., Aydinli, Atilla, Leburton, J.P. (Eds.). ISBN: OCLC Number: Notes: "Proceedings of the NATO Advanced Study Institute on Optical Spectroscopy of Low Dimensional Semiconductors, Ankara and Antalya, Turkey, September "--Title page verso.

the physics of low dimensional semiconductors to learn about recent developments and to discuss open questions in the area of optical spectroscopy of low dimensional semiconductors. The school turned out to be extremely fruitful and there was a great enthusiasm among the lecturers and students during the whole two weeks.

The book is. The Physics of Low-dimensional Semiconductors An Introduction. Get access. Angle-resolved photoemission spectroscopy and first-principles calculations study. Physical Review B, Vol. 75, Issue. 3, whose optical properties find application in lasers and other opto-electronic devices.

The book includes many exercises and will be invaluable Cited by: Low-dimensional systems have revolutionized semiconductor physics and had a tremendous impact on technology.

Using simple physical explanations, with reference to examples from actual devices, this book introduces the general principles essential to low-dimensional by: The author develops the effective-mass theory of excitons in low-dimensional semiconductors and describes numerical methods for calculating the Optical spectroscopy of low dimensional semiconductors book absorption including Coulomb interaction, geometry, and external fields.

The theory is applied to Fano resonances in low-dimensional semiconductors and the Zener breakdown in superlattices. Optical Spectroscopy of Semiconductor Nanostructures.

by E.L. Ivchenko (Author) ISBN ISBN Why is ISBN important. ISBN. This bar-code number lets you verify that you're getting exactly the right version or edition of a book. Cited by: This book shows the electronic, optical and lattice-vibration properties of the two-dimensional materials which are revealed by the Raman spectroscopy.

It consists Raman spectroscopy techniques, different kinds of two-dimensional materials and their physical properties. This book contains all the papers presented at the NATO workshop on "Optical Switching in Low Optical spectroscopy of low dimensional semiconductors book Systems" held in Marbella, Spain from October 6th to 8th, Optical switching is a basic function for optical data processing, which is of technological interest because of its potential parallelism and its potential speed.

Optical spectra of low-dimensional semiconductors Article in JOURNAL OF INFRARED AND MILLIMETER WAVES 22(6) December with 1 Reads How we measure 'reads'.

A 'read' is counted each time someone views a publication summary (such as the title, abstract, and list of authors), clicks on a figure, or views or downloads the full-text.

This chapter introduces the optical characterization of two-dimensional (2D) semiconductors by Raman spectroscopy, photoluminescence (PL) spectroscopy, and absorption spectroscopy.

It starts by presenting how Raman spectroscopy can be utilized to characterize the properties of 2D semiconductors such as crystal structures, strain, doping. This book presents an overview of the current understanding of the physics of zero-dimensional semiconductors.

It concentrates mainly on quantum dots of wide-gap semiconductors, but touches also on zero-dimensional systems based on silicon and III-V materials. Raman spectroscopy has been widely used to characterize low dimensional materials such as 1D (e.g., Carbon nanotubes) and 2D semiconductors (e.g., transition metal dichalcogenides) ((Dresselhaus et al., ).When the exciting laser wavelength coincides with the band gap of the semiconductor, the Raman intensity is enhanced significantly, of the order of ~10 3 –10 4, by.

Electroluminescence ; Electronic structure and luminescence of low-dimensional semiconductors ; Effects of high excitation in low-dimensional structures ; Stimulated emission and lasing in low-dimensional structures ; Silicon nanophotonics ; Photonic structures ; Spectroscopy of single semiconductor nanocrystals.

Luminescence of semiconductors is nowadays based on very firm background of solid state physics. The purpose of this book is to introduce the reader to the study of the physical principles underlying inorganic semiconductor luminescence phenomena. It guides the reader starting from the very introductory definitions over luminescence of bulk semiconductors and finishing at the Author: Ivan Pelant.

This book reviews up-to-date ideas of how the luminescence radiation in semiconductors originates and how to analyze it experimentally. The book fills a gap between general textbooks on optical properties of solids and specialized monographs on luminescence.

It is unique in its coherent treatment of the phenomenon of luminescence from the very introductory definitions. Abstract. The authors present the application of contactless electroreflectance (CER) spectroscopy to study optical transitions in low dimensional semiconductor structures including quantum wells (QWs), step-like QWs, quantum dots (QDs), quantum dashes (QDashes), QDs and QDashes embedded in a QW, and QDashes coupled with a by: Low-dimensional systems have revolutionized semiconductor physics and had a tremendous impact on technology.

Using simple physical explanations, with reference to examples from actual devices, this book introduces the general principles essential to low-dimensional semiconductors. What is an optical semiconductor.

Optical semiconductor devices are divided into two major groups: luminescent devices (light-emitting diodes and laser diodes), and light-receiving devices (solar cells and photo-detectors).

The wavelengths of the light depend on the optical semiconductor materials used. All the materials introduced in this book yield new optical phenomena originating from their mesoscopic and low-dimensional electronic characters and electron-lattice couplings, which offer a new research field of materials science as well as condensed-matter and optical physics.

Volumes 1 and 2 are interrelated but can be read independently. Quantum of optical absorption in two-dimensional semiconductors Hui Fanga,b,c, Hans A. Bechteld, Elena Plise, Michael C. Martind, Sanjay Krishnae, Eli Yablonovitcha,b,1, and Ali Javeya,b,c,1 aDepartment of Electrical Engineering and Computer Sciences, University of California, Berkeley, CA ; bMaterials Sciences Division, Lawrence Berkeley National.

Description: This monograph is concerned with the III-V bulk and low-dimensional semiconductors, with the emphasis on the implications of multi-valley bandstructures for the physical mechanisms essential for opto-electronic devices.

The optical response of such semiconductor materials is determined by many-body effects such as screening, gap. This review seeks to extend the scope of both the experimental and theoreticalwork carried out since I completed my review on the electronic, optical, andto a lesser extent, the transport properties of a variety of semiconductor quantumdots (QDs).

In addition to the many advances that have been made on topics suchas quantum confinement Cited by: 12 Electronic structure and luminescence of low-dimensional semiconductors; 13 Effects of high excitation in low-dimensional structures; 14 Stimulated emission and lasing in low-dimensional structures; 15 Silicon nanophotonics; 16 Photonic structures; Spectroscopy of single semiconductor nanocrystals; A ConvolutionAuthor: Ivan Pelant.

This textbook presents the basic elements needed to understand and engage in research in semiconductor physics. It deals with elementary excitations in bulk and low-dimensional semiconductors, including quantum wells, quantum wires and quantum dots.

The basic principles underlying optical nonlinearities are developed, including excitonic and many-body plasma. semiconductors Correlation effects Non-radiativerecombination Luminescence ofimpurities anddefects Luminescence 'fatigue' Problems References 10Stimulatedemission Spontaneousversus stimulated emission.

Optical gain Optical gain in semiconductors Two-dimensional optical spectroscopy of excitons in semiconductor quantum wells: Liouville-space pathway analysis Lijun Yang, 1Igor V.

Schweigert, Steven T. Cundiff,2 and Shaul Mukamel 1Chemistry Department, University of California, Irvine, California,USA 2JILA, University of Colorado and National Institute of Standards and Technology, Boulder, Colorado.

Optical Properties and Band Structure of Semiconductors, Volume 1 presents the experimental studies of the fundamental energy band structure of semiconductors and insulators. This book provides detailed information of the available measurement methods and results for a large number of both cubic and non-cubic materials.

This book reviews up-to-date ideas of how the luminescence radiation in semiconductors originates and how to analyze it experimentally. The book fills a gap between general textbooks on optical properties of solids and specialized monographs on luminescence.

Focusing on time-domain spectroscopy, the book presents detailed discussions on the underlying physics and interpretation methods of a variety of two-dimensional optical spectroscopic methods.

It illustrates how novel diagrammatic techniques are useful in graphically describing the associated nonlinear optical transition pathways and involved. Further chapters deal with subjects such as photoemission, infrared spectroscopy, intraband optical properties of low-dimensional semiconductor systems and modulation spectroscopy of semiconductors and semiconductor microstructures.

show moreAuthor: Minko Balkanski. All optical measurements of semiconductors rely on a fundamental understanding of their optical properties. In this chapter, a broad overview of the optical properties of semiconductors is given, along with numerous specific examples.

The optical properties of a semiconductor can be defined as any property that involves. Optical Characterization of Low-Dimensional Materials | 2 0 Drift of the sample with respect to the objective due to thermal contraction can cause the focal region to move out of the field of view.

Monitoring and relocating the targeted quantum material takes time and can introduce variability to a. Explore our list of Electronics - Semiconductors Books at Barnes & Noble®. Receive FREE shipping with your Barnes & Noble Membership. Due to COVID, orders may be delayed.

This invaluable textbook presents the basic elements needed to understand and research into semiconductor physics. It deals with elementary excitations in bulk and low-dimensional semiconductors, including quantum wells, quantum wires and quantum dots. The basic principles underlying optical.

Luminescence Spectroscopy of Semiconductors (H) OUP UK This book reviews up-to-date ideas of how the luminescence radiation in semiconductors originates and how to analyze it experimentally. The book fills a gap between general textbooks on optical properties of solids and specialized monographs on luminescence.

12 Electronic structure and. Purchase The Spectroscopy of Semiconductors, Volume 36 - 1st Edition. Print Book & E-Book. ISBNBook Edition: 1. Read "The Physics of Low-dimensional Semiconductors An Introduction" by John H.

Davies available from Rakuten Kobo. The composition of modern semiconductor heterostructures can be controlled precisely on the atomic scale to create low-d Brand: Cambridge University Press.

To distinguish the nature of the photogenerated species we use optical pump-terahertz spectroscopy. Two-dimensional semiconductors are photoexcited with optical pump pulses of pulse width 50 fs and the resulted photogenerated species (excitons or free charges) are probed by a single-cycle terahertz pulse.

Optical two dimensional Fourier transform spectra of excitonic resonances in semiconductors are measured and calculated. They provide insight into many-body interactions in direct gap semiconductors by separating the contributions to the coherent optical nonlinear response.Optical two-dimensional Fourier transform (2DFT) spectroscopy has been developed over the last decade as a powerful tool for studying a variety of physical systems, ranging from atoms to molecules to solids.

This review covers our use of 2DFT spectroscopy to study exciton dynamics in semiconductor nanostructures. In quantum wells, 2DFT spectroscopy confirms the .Barford’s book starts with a treatise of noninteracting π-electrons in conjugated polymers. Then, step by step, the author includes electron–lattice and electron–electron interactions.

He discusses the influence of those interactions on the ground-state dimerization and on dipole-allowed and dipole-forbidden excited states. In particular, Barford covers the weak-coupling limit, the Author: Jörg Fink.