Book Description
The book presents a detailed description of high-resolution x-ray scattering methods suitable for the investigation of the real structure of single-crystalline layers and multilayers, including structure defects in the layers and at the interfaces. Particular attention is devoted to lateral structures in semiconductors and semiconductor multilayers such as quantum wires and quantum dots. Both the theoretical background and the application of the methods are discussed. The second edition is extended to deal with lateral surface nanostructures such as gratings and dots, new examples for measuring layer thickness, lattice mismatch, and surface/interface roughness. The book will be an invaluable source for graduates and scientists.
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Fluid Flow Phenomena - A Numerical Toolkit (FLUID MECHANICS AND ITS APPLICATIONS Volume 55) (Fluid Mechanics and Its Applications)
P. Orlandi
Manufacturer: Springer
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ASIN: 0792360958 |
Book Description
This book deals with the simulation of the incompressible Navier-Stokes equations for laminar and turbulent flows. The book is limited to explaining and employing the finite difference method. It furnishes a large number of source codes which permit to play with the Navier-Stokes equations and to understand the complex physics related to fluid mechanics.
Numerical simulations are useful tools to understand the complexity of the flows, which often is difficult to derive from laboratory experiments. This book, then, can be very useful to scholars doing laboratory experiments, since they often do not have extra time to study the large variety of numerical methods; furthermore they cannot spend more time in transferring one of the methods into a computer language. By means of numerical simulations, for example, insights into the vorticity field can be obtained which are difficult to obtain by measurements.
This book can be used by graduate as well as undergraduate students while reading books on theoretical fluid mechanics; it teaches how to simulate the dynamics of flow fields on personal computers. This will provide a better way of understanding the theory. Two chapters on Large Eddy Simulations have been included, since this is a methodology that in the near future will allow more universal turbulence models for practical applications. The direct simulation of the Navier-Stokes equations (DNS) is simple by finite-differences, that are satisfactory to reproduce the dynamics of turbulent flows. A large part of the book is devoted to the study of homogeneous and wall turbulent flows.
In the second chapter the elementary concept of finite difference is given to solve parabolic and elliptical partial differential equations. In successive chapters the 1D, 2D, and 3D Navier-Stokes equations are solved in Cartesian and cylindrical coordinates. Finally, Large Eddy Simulations are performed to check the importance of the subgrid scale models. Results for turbulent and laminar flows are discussed, with particular emphasis on vortex dynamics.
This volume will be of interest to graduate students and researchers wanting to compare experiments and numerical simulations, and to workers in the mechanical and aeronautic industries.
Book Description
This is a first year graduate textbook in Linear Elasticity. It is written with the practical engineering reader in mind, dependence on previous knowledge of Solid Mechanics, Continuum Mechanics or Mathematics being minimized. Most of the text should be readily intelligible to a reader with an undergraduate background of one or two courses in elementary Mechanics of Materials and a rudimentary knowledge of partial differentiation. Emphasis is placed on engineering applications of elasticity and examples are generally worked through to final expressions for the stress and displacement fields in order to explore the engineering consequences of the results. The Topics covered were chosen with a view to modern research applications in Fracture Mechanics, Composite Materials, Tribology and Numerical Methods. Thus, significant attention is given to crack and contact problems, problems involving interfaces between dissimilar media, thermo elasticity, singular asymptotic stress fields and three-dimensional problems. This second edition includes new chapters on antiplane stress systems, Saint-Venant torsion and bending and an expanded section on three-dimensional problems in spherical and cylindrical coordinate systems, including axisymmetric torsion of bars of non-uniform circular cross-section. It also includes over 200 end-of-chapter problems, which are expressed wherever possible in the form they would arise in engineering - i.e. as a body of a given geometry subjected to prescribed loading - instead of inviting the student to 'verify' that a given candidate stress function is appropriate to the problem. Solution of these problems is considerably facilitated by the use of modern symbolic mathematical languages such as Maple® and Mathematica® and electronic files and hints on this method of solution can be accessed at the web site www.elasticity.org.
Customer Reviews:
An average treatment - many misprints and unstated assumptions........2006-06-04
Unfortunately, Barber's Elasticity is marred by a good deal of errata and does not make clear important assumptions in several derivations, most notably in dealing with curved beams. There are better texts available on this subject.
Excellent.......1999-07-12
This book will introduce governing equations of linear elasticity and will focus on solutions of boundary value problems in both two and three dimensions using several different methods.
Average customer rating:
- Rigorous but not complete
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Disordered Materials: An Introduction (Advanced Texts in Physics)
Paolo M. Ossi
Manufacturer: Springer
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Binding: Hardcover
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ASIN: 3540296093 |
Book Description
This self-contained text introduces the physics of structurally disordered condensed systems at the level of advanced undergraduate and graduate students. Among the topics, the geometry and symmetries of highly regular structures, the various kinds of disorder, the phenomenology and the main theories of the glass transition, the experimental investigation on the structure and microscopic dynamics of amorphous systems and the pertinent modelling, the structure and stability of noble gas, metal and carbon clusters, and their evolution with cluster size, nanostructured solids, the structure of quasicrystals and their relation to nanocrystalline and amorphous solids.
From the reviews of the first edition: "The text is clearly presented, amply illustrated and has approximately 45 references with an equivalent amount of further reading […] it provides a fresh viewpoint which makes it well worth careful reading... [and] provides a stimulating and novel coverage of a difficult subject area." Glass Technology
Customer Reviews:
Rigorous but not complete.......2003-08-21
I am a materials science engineer and read this book to learn about diamond-like carbon, which is a disordered material. This book covers a lot of topics, and ues a fair deal of equations and figures. It adequately covers most topics about disordered materials, though I could not find much information about diamond-like carbon. I would not recommend this book as an introductory text on the subject, but it is good for a reference. The text assumes the reader has fairly good knowledge of geometry, math, and solid state science, along with materials science. Much of the text could be rewritten to make it more readable, without reducing content.
Average customer rating:
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Field Effect in Semiconductor-Electrolyte Interfaces: Application to Investigations of Electronic Properties of Semiconductor Surfaces
Pavel P. Konorov ,
Adil M. Yafyasov , and
Vladislav B. Bogevolnov
Manufacturer: Princeton University Press
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ASIN: 0691121761 |
Book Description
This book presents a state-of-the-art understanding of semiconductor-electrolyte interfaces. It provides a detailed study of semiconductor-electrolyte interfacial effects, focusing on the physical and electrochemical foundations that affect surface charge, capacitance, conductance, quantum effects, and other properties, both from the point of view of theoretical modeling and metrology. The wet-dry interface, where solid-state devices may be in contact with electrolyte solutions, is of growing interest and importance. This is because such interfaces will be a key part of hydrogen energy and solar cells, and of sensors that would have wide applications in medicine, genomics, environmental science, and bioterrorism prevention.
The field effect presented here by Pavel Konorov, Adil Yafyasov, and Vladislav Bogevolnov is a new method, one that allows investigation of the physical properties of semiconductor and superconductor surfaces. Before the development of this method, it was impossible to test these surfaces at room temperature. The behavior of electrodes in electrolytes under such realistic conduction conditions has been a major problem for the technical realization of systems that perform measurements in wet environments. This book also describes some material properties that were unknown before the development of the field effect method.
This book will be of great interest to students and engineers working in semiconductor surface physics, electrochemistry, and micro- and nanoelectronics.
Book Description
This new edition of the well-received introduction to solid-state physics provides a comprehensive overview of the basic theoretical and experimental concepts of materials science. Experimental aspects and laboratory details are highlighted in separate panels that enrich text and emphasize recent developments.
Notably, new material in the third edition includes sections on important devices, aspects of non- periodic structures of matter, phase transitions, defects, superconductors and nanostructures.
Students will benefit significantly from solving the exercises given at the end of each chapter. This book is intended for university students in physics, materials science and electrical engineering. This edition has been thoroughly updated to maintain its usefulness as modern text and reference.
Customer Reviews:
i disagree.......2006-07-03
i dont have it in front of me for a more detailed review, but the text is popular with german students and only after it became more widespread was it translated into english and redistributed. it's a fine introductory text (and better than kittel in my opinion, which reads more like a recipe-book).
Seems very incomplete.......2001-03-19
We used this text in an introductory solid state course. Overall, it seems that the text is far too brief and doesn't thoroughly explain the material enough for an introductory course. There are very few examples/applications. The problems in the chapter require research outside of what is in the text. It leaves out a lot of important details. I would really suggest looking elsewhere for a good solid state introduction.
Limited audience.......2000-02-23
I used this book in a course which was supposed to be an introduction to solid state. Know some basic ideas in crystal structure, quantum mechanics, statistical mechanics, advanced and partial differential equations and Fourier anlysis and then you'll begin to be ready to understand this text. Kittel's Solid State text is slightly more helpful (but only slightly). The book is completely devoid of examples, yet there are sections at the end of each chapter involving current applications and experiments in condensed matter physics and materials science. Exercises require a leap of understanding from the contents of the chapter before them. Some experience with a computer language may also be necessary. I wouldn't recommend this book for most undergrads.
Customer Reviews:
Advanced users only.......2002-01-01
The title of the book may be misleading.
Attention, this book is for advanced readers in Condensed matter physics. Actually, the book is mostly consisted of some good papers selected by by Anderson. A beginner can read this after he get to know the "basic notions" from basic books.
A very useful Guide to Condense Matter.......2001-04-08
In fact, although it was been published almost twenty years ago, But most ideas in it were very classical and very sightful to Condense Matter So you caould see that many papers in the publication in fact cites this book . It's a very guide to the matter world !
Average customer rating:
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Artificial Muscles: Applications of Advanced Polymeric Nanocomposites
Mohsen Shahinpoor ,
Kwang J. Kim , and
Mehran Mojarrad
Manufacturer: Taylor & Francis
ProductGroup: Book
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ASIN: 1584887133 |
Book Description
Smart materials are the way of the future in a variety of fields, from biomedical engineering and chemistry to nanoscience, nanotechnology, and robotics. Featuring an interdisciplinary approach to smart materials and structures, Artificial Muscles: Applications of Advanced Polymeric Nanocomposites thoroughly reviews the existing knowledge of ionic polymeric conductor nanocomposites (IPCNCs), including ionic polymeric metal nanocomposites (IPMNCs) as biomimetic distributed nanosensors, nanoactuators, nanotransducers, nanorobots, artificial muscles, and electrically controllable intelligent polymeric network structures. Authored by one of the founding fathers of the field, the book introduces fabrication and manufacturing methods of several electrically and chemically active ionic polymeric sensors, actuators, and artificial muscles, as well as a new class of electrically active polymeric nanocomposites and artificial muscles. It also describes a few apparatuses for modeling and testing various artificial muscles to show the viability of chemoactive and electroactive muscles. The authors present the theories, modeling, and numerical simulations of ionic polymeric artificial muscles' electrodynamics and chemodynamics. In addition, they feature current industrial and medical applications of IPMNCs. By covering the fabrication techniques of and novel developments in advanced polymeric nanocomposites, this book provides a solid foundation in the subject while stimulating further research.
Book Description
Professor Phillips provides an accurate exploration and solid foundation for students and researchers of this fast-growing field.
Solid state physics continues to be the fastest-growing sub-discipline in physics. This much anticipated new book provides ample background that underpins the principles of solid state physics, and moves quickly to an overview of current research in this fast-moving field. Upper division undergraduates and graduate students in physics who wish to pursue solid state physics research must master old topics, as well as problems of current interest. This book serves that purpose, and fills students' needs.
Customer Reviews:
Good overview of standard theory and more modern developments.......2007-01-22
Condensed matter physics has been and will always be the most important branch of physics, due mostly to its role in technological developments. Advances in medicine have also depended directly on advances in condensed matter physics, along with advances in materials science and computer technology. Armies of researchers and billions of research dollars have poured into this field, and throughout its history it has been marked by brilliant developments. Many of these developments are discussed in this book, which targets a readership that already has had exposure to condensed matter physics and statistical mechanics at the elementary level. Although somewhat short considering the subject matter, the author is still able to give the details on the subjects that have given the most surprises to researchers in recent decades.
For example, this book has one of the best overviews of the Kondo problem of all the current books on advanced condensed matter physics. The author presents the problem as one that will definitely need a treatment not possible in the context of mean-field theory, since the latter is mostly applicable to high temperatures. The goal is to study the affects of local magnetic moments on the transport and magnetic properties of a particular metal and how these moments behave as the temperature is lowered. Interestingly, and of great surprise when it was discovered, above the so-called Kondo temperature, the magnetic susceptibility of a magnetic impurity obeys the usual Curie law. However below the Kondo temperature it approaches a constant. Thus magnetism ceases at low temperatures, which definitely countered what was expected, namely that there is always magnetization below the Curie temperature. The analysis of the problem boils down to studying the interaction of the spin of the impurity with the conduction electrons, and the original solution by Kondo diverged at temperatures below the Kondo temperature. An approach based on the renormalization group (ala Kenneth Wilson) finally solved the Kondo problem, and this approach is discussed, along with the others that were proposed before it and based on second-order perturbation theory. These developments are discussed in the book.
The treatment of the electron gas, the Hartree-Fock approximation, and plasma oscillations is fairly standard but detailed. For the noninteracting electron gas the author actually calculates the pressure in the ground state and quotes the value: one million atmospheres (!) with this coming solely from the Pauli exclusion principle. In his discussion of the Wigner solid, the author mentions, but does not discuss in detail, the experiments in the dilute two-dimensional electron gas that indicate a metal-insulator transition in this system for zero magnetic field. A reference is given however for readers who want to familiarize themselves with what was known experimentally at the time of publication. Interest in the two-dimensional electron gas has waxed and waned over the last few decades. This reviewer studied this system in the context of metal-insulator-semiconductor structures with narrow gap semiconductors in the early 1980's.
Also discussed in the book, and of great interest to other areas of physics and mathematics such as the theory of exactly solved models in statistical mechanics and conformal field theory, is the topic of bosonization. The author motivates this subject by considering the case of the dynamics of the Fourier components of the electron density for the interacting electron gas in the regime where plasma oscillations exist. This dynamics is governed by a harmonic oscillator equation, which gives credence to the view that plasma oscillations can be viewed as bosonic excitations in the interacting electron gas. A natural question to ask then is whether this can be generalized, namely can one start with a system governed by Fermi-Dirac statistics and map it into one that is governed by Bose-Einstein statistics. A general procedure for doing this is unknown, but it has been done rigorously for the case of interacting electrons in one dimension. The author discusses this for the case of the one-dimensional Hubbard model, which when subjected to bosonization becomes the Luttinger liquid. He reminds the reader though that one must not impute too much to bosonization in this case since it is merely an equivalence of their equations of motion. He does note however that for the case of interacting electrons in one-dimension there is interesting physics that can be illuminated by the process of bosonization, namely that the electron in this case can be viewed as a composite particle consisting of a `holon' and a `spinon', both of which obey Bose statistics.
The most interesting part of the book, and one that is full of lively discussion, is the one on localization in disordered solids. At least for Anderson localization, which was the first considered historically, the dependence on dimension is obvious, with the Anderson transition only occurring in dimensions three or more. The absence of the transition in dimensions less than three is perhaps not too surprising if one remembers the results in rigorous statistical quantum physics about the absence of phase transitions in dimensions this low. But here one is studying the occurrence of a transition between insulating and conducting regimes, which is dependent on the degree of disorder, and not the temperature (the insulator-metal transition is thus a `quantum phase transition'). It is clear from the perusal of this chapter that localization is a difficult problem whose study requires many tools, each one of these by itself insufficient to capture the entire phenomenon. Indeed, the Boltzmann transport theory cannot describe the Anderson transition, due to its insistence that the mean free path be greater than the lattice spacing. If one uses Green functions, one must compute the site self-energy, which as the author shows (but briefly) can be done but it masks the essential physics of the localization transition. Thus the author resorts to scaling theory, which via a single parameter, the conductance, completely characterizes the localization transition.
luck.......2006-06-08
After the book of A/M solid state physics, there is no consensus on the most suitable and modern solid state physics textbook. One of the main reason is the rapid developements of some fancy theory, like bosonization, RG, etc after 70s. This book written by Phillips convers almost
all the contemporary topics in condensed matter theory except the high-Tc part. On this ground, this book is worthy recommendation.
A friendly, good introduction for all the modern concepts.......2004-01-15
The author gives a very good introduction to the topics most researchers in the Condensed Matter community are intersted in. This is good for both theorists and experimentalists as beginners. For theorists, this book gives quickly physics images, which is relatively much easier than reading all the original papers; for experimentalists, this gives very good reviews what the theorists are working about and how are they related to the real world, while NOT MUCH MATH is needed for going through this book.
So this book helps any beginner in the Condensed Matter research to go to the frontier quickly.
I also llike the free-style language the author used in this book --- reading the book is like talking with a friend in the tea time.
One thing I don't like about the book is, for some critical topics (like the localizations), the author tried to explain some hard problems in an easy way, while sometimes he failed in doing it clearly and precisely. But again this book is not a math book, and the clear physics pictures it describes already make it one of the best introductory textbooks for these "advanced" topics.
A friendly, good introduction for all the modern concepts.......2004-01-14
The author gives a very good introduction to the topics most researchers in the Condensed Matter community are intersted in. This is good for both theorists and experimentalists as beginners. For theorists, this book gives quickly physics images, which is relatively much easier than reading all the original papers; for experimentalists, this gives very good reviews what the theorists are working about and how are they related to the real world, while NOT MUCH MATH is needed for going through this book.
So this book helps any beginner in the Condensed Matter research to go to the frontier quickly.
I also llike the free-style language the author used in this book --- reading the book is like talking with a friend in the tea time.
One thing I don't like the book is, for some critical topics (like the localizations), the author tried to explain some hard problems in an easy way, while sometimes he failed in doing it clearly and precisely. But again this book is not a math book, and the clear physics pictures it describe already make it one of the best introductory textbooks for these "advanced" topics.
A concise but thorough treatment of Adv. Solid State !.......2003-12-13
I just attended a course based on this book and all I can say is wow.
P. Philips avoids falling into excessive formalism and manages to present
the essence of each subject.
Readers with preparation in the introductory S. State will certainly
benefit from the straight and insightful treatment of the subjects.
Book Description
This volume explains the fundamental concepts and theoretical techniques used to understand the properties of quantum systems used to understand the properties of quantum systems having large numbers of degrees of freedom. A number of complimentary approaches are developed, including perturbation theory; nonpurturbative approximations based on functional integrals; general arguments based on order parameters; symmetry, and Fermi liquid theory; and stochastic methods. Each approach provides its own insights and quantitative capabilities, and in conjunction provide a powerful framework for understanding a wide variety of physical systems. Written at a level for graduate students with no prior background in manybody theory, this classic text is intended for physicists in solid state physics, field theory, atomic physics, condensed matter physics, quantum chemistry, and nuclear physics.
Customer Reviews:
Clear, precise, and modern.......2002-09-11
A great physics book for field theory applied to condensed
matter and sometimes nuclear physics problems. The authors
are EXTREMELY careful mathematically and really don't skip
any steps or shove stuff under the rug; in fact, the first
chapter is just all math about how to do integrals and path
integrals and field integrals and deal with Grassman numbers.
A bit unusual for a physics book, but that's their style.
The rest of the book deals with the usual and other material:
zero-temperature Green's functions and perturbation theory
(for energy, Green's function, etc.) The treatment is detailed
and relatively exhaustive. Then there is the same for finite-
temperature. The earlier sections on linear response are
concise and one of the best treatments of the subject I have
seen leading directly to the fluctuation dissipation expression
(after this book I realized this vaunted "fluctuation-dissipation" that no one can explain is just
a straightforward thing about commutators and pert. theory).
The book also has other good stuff: a chapter on mean field theory, Landau-Ginzburg theory, order parameters, and a nice
discussion about spontaneous symmetry breaking that helps
clarify a bunch of stuff. Then there is a whole chapter on
further aspects of one-particle Green's functions (Dyson
equation, solving for poles, quasiparticles, satellites, etc.)
that is pretty good and gets the physical point across. There
is also a chapter on statistical (monte carlo, numerical, etc.)
methods for doing quantum many body problems. While some of
the methods are not the most up to date or modern, the basics
are all there (Monte Carlo, Hubbard-Strataonvich (spelling?),
inverting matrices via Monte Carlo, some stuff about lattice
systems, Langevin equation simulation for Monte Carlo, updating
problems, etc.) There is also a chapter on more advanced
functional integration stuff. Also there is a nice description
of the loop expansion and whatnot.
The book is very well written, has no errors as far as I can
tell, and is exhaustive on what it treats. The problems at
the end of the first few chapters deal with physics problems
and help build intuition whereas the texts in these chapters
are more formal. The book could use some more physical insights
sprinkled throughout, but that is not too much of a drawback.
The book is based on functional integration (Feynman integral)
methods for field theory: this is the modern way folks do it
and it is a powerful way of doing field theory both to
derive results, connect results, do expansions and what not,
and also for certain kinds of monte carl computations. So
having read this, the reader is up to date on a pretty modern
view of field theory in condensed matter (and somewhat on
nuclear physics).
Highly recommended unless you can't stand precise and long
mathematical treatments. My only misgiving is that sometimes
I wish the authors provided more physical insights for certain
concepts and gave some examples rather than "just the math";
but they do this in other parts of the book, so perhaps
my complaint, which is not that serious, is more about the
uneven way this is done. Nevertheless, this is 5/5 and a book
you will read many times and learn from many times.
An important book for beginner cond-mat physicists and more........2000-04-10
A very good introduction to the many particle systems, includes all from the basics of coherent states to very complex parts of theory.
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