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000796565 019__ $$a999532527
000796565 020__ $$a9783319615240$$q(electronic book)
000796565 020__ $$a3319615246$$q(electronic book)
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000796565 08204 $$a539.7/2$$223
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000796565 1001_ $$aNešković, N.$$q(Nebojša),$$d1949-$$eauthor.
000796565 24510 $$aRainbows in channeling of charged particles in crystals and nanotubes /$$cNebojša Nešković, Srdjan Petrović, Marko Ćosić.
000796565 264_1 $$aCham, Switzerland :$$bSpringer,$$c2017.
000796565 300__ $$a1 online resource (x, 194 pages) :$$billustrations.
000796565 336__ $$atext$$btxt$$2rdacontent
000796565 337__ $$acomputer$$bc$$2rdamedia
000796565 338__ $$aonline resource$$bcr$$2rdacarrier
000796565 4901_ $$aLecture notes in nanoscale science and technology,$$x2195-2159 ;$$vvolume 25
000796565 504__ $$aIncldues bibliographical refernces and indexes.
000796565 5050_ $$aPrologue; Contents; Chapter 1: Rainbows; 1.1 Optical Rainbows; 1.2 Particle Rainbows; 1.2.1 Atomic Rainbows; 1.2.2 Coulomb and Nuclear Rainbows; 1.2.3 Surface Rainbows; 1.2.4 Crystal Rainbows; Chapter 2: Ion Channeling; 2.1 Basic Facts; 2.2 Interaction Potentials; 2.3 Computer Simulations; 2.3.1 Applicability of Classical Mechanics; 2.3.2 Continuum String Model; 2.3.3 Binary Collision Model; Chapter 3: Crystal Rainbows; 3.1 Ion Channeling in Very Thin Crystals; 3.1.1 Model of Crystal Rainbows; 3.1.2 First Measurements of the Crystal Rainbows; 3.2 Crystal Rainbows as Elementary Catastrophes
000796565 5058_ $$a3.2.1 Crystal Rainbow Effect as a Catastrophic Effect3.2.2 The 4X9 Catastrophe as the Organizing Center of Crystal Rainbows; 3.3 Zero-Degree Focusing Effect; 3.4 Theory of Crystal Rainbows; Chapter 4: Rainbows in Proton Channeling in Silicon Crystals; 4.1 Rainbow Interaction Potentials; 4.1.1 High-Resolution Measurements of the Crystal Rainbows; 4.1.2 Interaction Potentials; 4.1.3 Morphological Method of Extraction of the Interaction Potentials; 4.2 Inverse Transmission; 4.3 Superfocusing Effect; 4.3.1 Axial Focusing; 4.3.2 Rainbow Subatomic Microscopy
000796565 5058_ $$a4.3.3 Measurement of the Superfocusing Effect4.4 Doughnut Effect; 4.4.1 Explanation of the Doughnut Effect; 4.4.2 High-Resolution Measurement of the Doughnut Effect; Chapter 5: Rainbows with Protons and Carbon Nanotubes; 5.1 Rainbows with a Straight Very Short Bundle of Nanotubes; 5.1.1 Zero-Degree Focusing Effect; 5.1.2 Rainbow Effect; 5.2 Spatial and Angular Rainbows with a Bent Very Short Nanotube; 5.2.1 Spatial and Angular Distributions; 5.2.2 Spatial and Angular Rainbows; 5.3 Spatial and Angular Rainbows with Straight Very Long Nanotubes; 5.3.1 Spatial Rainbow Effect
000796565 5058_ $$a5.3.2 Angular Rainbow Effect5.3.3 Trajectories; Chapter 6: Rainbows with Positrons and Carbon Nanotubes; 6.1 Quantum Mechanical Theory of Rainbow Channeling; 6.1.1 Interaction Potentials; 6.1.2 Classical Approach; 6.1.3 Quantum Mechanical Approach; 6.2 Spatial and Angular Primary Rainbows; 6.2.1 Classical Rainbows; 6.2.2 Quantum Rainbows; 6.2.2.1 Quantum Spatial Primary Rainbows for L = 50 nm; 6.2.2.2 Quantum Spatial Primary Rainbows for L = 100 nm; 6.2.2.3 Quantum Angular Primary Rainbows for L = 250 nm; Epilogue; References; Author Index; Subject Index
000796565 506__ $$aAccess limited to authorized users.
000796565 520__ $$aThis book discusses the effects, modeling, latest results, and nanotechnology applications of rainbows that appear during channeling of charged particles in crystals and nanotubes. The authors begin with a brief review of the optical and particle rainbow effects followed by a detailed description of crystal rainbows, which appear in ion channeling in crystals, and their modeling using catastrophe theory. The effects of spatial and angular focusing of channeled ions are described, with special attention given to the applications of the former effect to subatomic microscopy. The results of a thorough study of the recent high-resolution channeling experiments performed with protons of energies between 2.0 and 0.7 MeV and a 55 nm thick silicon crystal are also provided. This study opens up the potential for accurate analysis of very thin crystals. Also presented are recent results related to rainbows occurring in proton transmission through carbon nanotubes, and a detailed quantum consideration of the transmission of positrons of an energy of 1 MeV through very short carbon nanotubes. This process is determined by the rainbow effect. The initial positron beam is represented as an ensemble of non-interacting Gaussian wave packets, and the principal and supernumerary primary rainbows appearing in the spatial and angular distributions of transmitted positrons are clearly identified. They are explained by the effects of wrinkling, concentration and coordination of the wave packets.
000796565 588__ $$aOnline resource; title from PDF title page (SpringerLink, viewed August 7, 2017).
000796565 650_0 $$aParticles (Nuclear physics)
000796565 650_0 $$aRainbows.
000796565 650_0 $$aCrystallography.
000796565 650_0 $$aNanotubes.
000796565 7001_ $$aPetrović, S.$$q(Srdjan),$$d1964-$$eauthor.
000796565 7001_ $$aĆosić, Marko,$$eauthor.
000796565 830_0 $$aLecture notes in nanoscale science and technology ;$$vv. 25.
000796565 852__ $$bebk
000796565 85640 $$3SpringerLink$$uhttps://univsouthin.idm.oclc.org/login?url=http://link.springer.com/10.1007/978-3-319-61524-0$$zOnline Access$$91397441.1
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000796565 980__ $$aEBOOK
000796565 980__ $$aBIB
000796565 982__ $$aEbook
000796565 983__ $$aOnline
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