Editors Franco Bassani, Scuola Normale Superiore, Pisa, Italy Gerald L Liedl, Purdue University, West Lafayette, IN, USA Peter Wyder, Grenoble High Magnetic Field Laboratory, Grenoble, France Editorial Advisory Board Vladimir Agranovich, Russian Academy of Sciences, Moscow, Russia Angelo Bifone, GlaxoSmithKline Research Centre, Verona, Italy Riccardo Broglia, Universita degli Studi di Milano, Milano, Italy Kikuo Cho, Osaka University, Osaka, Japan Ge!rard Chouteau, CNRS and MPI-FKF, Grenoble, France Roberto Colella, Purdue University, West Lafayette, IN, USA Pulak Dutta, Northwestern University, Evanston, IL, USA Leo Esaki, Shibaura Institute of Technology, Japan Jaap Franse, Universiteit van Amsterdam, Amsterdam, The Netherlands Alexander Gerber, Tel Aviv University, Tel Aviv, Israel Ron Gibala, University of Michigan, Ann Arbor, MI, USA Guiseppe Grosso, Universita" di Pisa, Pisa, Italy Jurgen M Honig, Purdue University, West Lafayette, IN, USA Massimo Inguscio, Dipartmento di Fisica e L.E.N.S., Firenze, Italy A G M Jansen, Institut Max Planck, Grenoble, France Th W J Janssen, Katholieke Universiteit Nijmegen, Nijmegen, The Netherlands Giorgio Margaritondo, Ecole Polytechnique Federale de Lausanne, Lausanne, Switzerland Emmanuel Rimini, Universita di Catania, Catania, Italy Robin D Rogers, The University of Alabama, Tuscaloosa, AL, USA John Singleton, Los Alamos National Laboratory, Los Alamos, NM, USA Carl H Zweben, Devon, PA, USA INTRODUCTION Physics is the paradigm of all scientific knowledge. Over the centuries it has evolved to a complexity that has resulted in a separation into various subfields, always connected with one another and very difficult to single out.FreemanDyson,inhisbeautifulbook‘InfiniteinAllDirections’,distinguishestwoaspectsofphysicsand twotypes ofphysicists: the unifiersandthe diversifiers. The unifiers lookforthe most general lawsof nature, likethe universal attraction betweenmassesandelectriccharges,the lawsofmotion,relativityprinciples,the simplest elementary particles, the unification of all forces, symmetry violation and so on. The diversifiers considertheimmensevarietyofnaturalphenomena,infiniteintheirextension,trytoexplainthemonthebasis ofknowngeneralprinciples,andgeneratenewphenomenaanddevicesthatdonotexistinnature.Evenatthe beginningofmodernscienceGalileoGalilei,besidesstudyingthelawsofmotionandlayingdowntheprinciple of relativity, was interested in the phenomenon of fluorescence and disproved the theories put forward at his time. He was both a unifier and a diversifier. The full explanation of fluorescence had to await the advent of quantum mechanics, as did the explanation of other basic phenomena like electrical conductivity and spectroscopy. The past century witnessed an explosive expansion in both aspects of physics. Relativity and quantum mechanics were discovered and the greatest of the unifiers, Albert Einstein, became convinced that all reality couldbecomprehendedwithasimplesetofequations.Ontheotherhandawiderangeofcomplexphenomena was explained and numerous new phenomena were discovered. One of the great diversifiers, John Bardeen, explained superconductivity and invented the transistor. In physics today we encounter complex phenomena in the behavior of both natural and artificial complex systems,inmatterconstitutedbymanyparticlessuchasinteractingatoms,incrystals,inclassicalandquantum fluids as well as in semiconductors and nanostructured materials. Furthermore, the complexity of biological matterandbiologicalphenomenaarenowmajorareasofstudyaswellasclimatepredictiononaglobalscale. Allofthishasevolvedintowhatwenowcall‘‘condensedmatterphysics’’.Thisisamorecomprehensiveterm than‘‘solidstatephysics’’fromwhich,whentheelectronicpropertiesofcrystalsbegantobeunderstoodinthe thirties, it originated in some way. Condensed matter physics also includes aspects of atomic physics, particularly when the atoms are manipulated, as in Bose–Einstein condensation. It is now the largest part of physics and it is where the greatest number of physicists work. Furthermore, it is enhanced through its connectionswithtechnologyandindustry.Incondensedmatterphysicsnewphenomena,newdevices,andnew principles,suchasthe quantum Halleffect,are constantlyemerging.Forthis reasonwe thinkthat condensed matterisnowtheliveliestsubfieldofphysics,andhavedecidedtoaddressitinthepresentEncyclopedia.Our focus is to provide some definitive articles for graduate students who need a guide through this impenetrable forest,researcherswhowantabroaderviewintosubjectsrelatedtotheirown,engineerswhoareinterestedin emergingandnewtechnologiestogetherwithbiologistswhorequireadeeperinsightintothisfascinatingand complex field that augments theirs. InthisEncyclopediawehaveselectedkeytopicsinthefieldofcondensedmatterphysics,providedhistorical backgroundtosomeofthemajorareasanddirectedthereader,throughdetailedreferences,tofurtherreading resources. Authors were sought from those who have made major contributions and worked actively in the viii INTRODUCTION areaofthetopic.Weareawarethatcompletenessinsuchaninfinitedomainisanunattainabledreamandhave decidedtolimitourefforttoasix-volumeworkcoveringonlythemainaspectsofthefield,notallofthemin comparable depth. AsignificantpartoftheEncyclopediaisdevotedtothebasicmethodsofquantummechanics,asappliedto crystals and other condensed matter. Semiconductors in particular are extensively described because of their importanceinthemoderninformationhighways.Nanostructuredmaterialsareincludedbecausetheabilityto produce substances which do not exist in nature offers intriguing opportunities, not least because their propertiescanbetailoredtoobtainspecificdeviceslikemicrocavitiesforlightconcentration,speciallasers,or photonicbandgapmaterials.Forthesamereasonsopticalpropertiesaregivenspecialattention.Wehavenot, however,neglectedfoundationaspectsofthefield(suchasmechanicalproperties)thatarebasicforallmaterial applications, microscopy which now allows one to see and to manipulate individual atoms, and materials processing which is necessary to produce new devices and components. Attention is also devoted to the ever- expandingroleoforganicmaterials,inparticularpolymers.Specificefforthasbeenmadetoincludebiological materials, which after the discovery of DNA and its properties are now being understood in physical terms. Neuroscience is also included, in conjunction with biological phenomena and other areas of the field. Computational physics and mathematical methods are included owing to their expanding role in all of condensedmatterphysicsandtheirpotentialinnumerousareasofstudyincludingapplicationsinthestudyof proteinsanddrugdesign.Manyarticlesdealwiththedescriptionofspecificdeviceslikeelectronandpositron sources, radiation sources, optoelectronic devices, micro and nanoelectronics. Also, articles covering essential techniques such as optical and electron microscopy, a variety of spectroscopes, x-ray and electron scattering and nuclear and electron spin resonance have been included to provide a foundation for the characterization aspect of condensed matter physics. We are aware of the wealth of topics that have been incompletely treated or left out, but we hope that by concentrating on the foundation and emerging aspects of the infinite extension of condensed matter physics these volumes will be generally useful. Wewishtoacknowledgethefruitfulcollaborationofthemembersofthescientificeditorialboardandofthe Elsevier editorial staff. Special thanks are due to Giuseppe Grosso, Giuseppe La Rocca, Keith Bowman, Jurgen Honig, Roberto Colella, Michael McElfresh, Jaap Franse, and Louis Jansen for their generous help. Franco Bassani, Peter Wyder, and Gerald L Liedl Permission Acknowledgments The following material is reproduced with kind permission of Nature Publishing Group Figure 12 of Ionic and Mixed Conductivity in Condensed Phases Figure 1 of Porous Silicon Figure 5 of Quasicrystals, Electronic Structure of Figure 2 of Superconductivity: Flux Quantization http://www.nature.com/nature The following material is reproduced with kind permission of the American Association for the Advancement of Science Figure 6 of Biomolecules, Scanning Probe Microscopy of Figure 4 of Excitons: Theory Figures 5, 6 and 7 of Genetic Algorithms for Biological Systems Figures 1 and 3 of Rhodopsin and the First Step in Vision Figures 4 and 5 of Scattering, Inelastic: Electron http://www.sciencemag.org The following material is reproduced with kind permission of Taylor & Francis Ltd Figure 5 of Ionic and Mixed Conductivity in Condensed Phases Figure 2 of Semiconductor Nanostructures http://www.tandf.co.uk/journals The following material is reproduced with kind permission of Oxford University Press Table 1 of Crystal Tensors: Applications Figure 2 of Cyclotron Resonance: Metals Figure 4 of Magnetoresistance Techniques Applied to Fermi Surfaces http://www.oup.com A Acoustics: Physical Principles and Applications to Condensed Matter Physics J DMaynard,ThePennsylvania StateUniversity, line of liquid helium. For the field of supercon- UniversityPark, PA,USA ductivity, a paper on acoustic attenuation was in- &2005,ElsevierLtd.AllRightsReserved. cluded as one of the relatively small number of selected reprints on superconductivity published by the American Institute of Physics. Acoustic measure- ments are among the first performed whenever a material involving novel physics is discovered. Mod- Introduction ern acoustic techniques, discussed below, can probe For many condensed matter systems, including liq- thepropertiesofsamplesonlyafewhundredmicrons uidsaswellassolids,acousticmeasurementsprovide in size and nanoscale thin films, and may be utilized a crucial probe of important and fundamental phys- in practical applications such as micro-electro-me- icsofthesystem.Inthecaseofsolids,oneofthefirst chanical systems (MEMS). Acoustic measurements fundamental properties to be determined would be provide significant information about condensed the atomic structure, defined by the minimum in the matter systems, and their accurate and precise meas- freeenergywithrespecttothepositionsoftheatoms. urement is certainly important. Thenextfundamentalcharacteristicofinterestmight be the curvature of the free energy in the vicinity of the minimum, and this would be manifest in the Acoustics in Solids elastic constants for the material. As derivatives of the free energy, elastic constants are closely connect- For solids, acoustic phenomena reflect the elastic edtothermodynamicpropertiesofthematerial;they properties of the material. Interest in elasticity dates can be related to specific heat, Debye temperature, back to Galileo and other philosophers in the seven- the Gruneisen parameter, and they can be used to teenth century, who were interested in the static checktheoreticalmodels.Extensivequantitativecon- equilibriumofbendingbeams.Withthebasicphysics nections may be made if the elastic constants are introduced by Hooke in 1660, the development of known as functions of temperature and pressure. the theory of elasticity followed the development of Acoustic measurements not only probe lattice prop- the necessary mathematics, with contributions from erties,theyarealsosensitiveprobesoftheenvironm- Euler, Lagrange, Poisson, Green, etc., and the result- ent in which all interactions take place, and may be ing theory was summarized in the treatise by A E H used to study electronic and magnetic properties Love in 1927. (e.g., through magnetostriction effects). As will be Acoustic and elastic properties of solids are quan- discussedlater,acousticmeasurementsinvolvetensor tifiedinasetofelasticconstants.Theseconstantsare quantities,andthuscanprobeanisotropicproperties like spring constants, relating forces, and displace- of crystals. The damping of elastic waves provides ments, and they may be measured with a static tech- information on anharmonicity and on coupling with nique, in which a displacement is measured as a electrons and other relaxation mechanisms. One of linear response to a small applied force. However, it the most important features of acoustic measure- was long ago learned that a better method is to ments is that they provide a sensitive probe of phase measure an elastic vibration, as found, for example, transitionsandcriticalphenomena;importantexam- in a propagating sound wave. Most existing com- ples,inadditiontotheobviousexampleofstructural pletesetsofelasticconstantsformaterialshavebeen transitions in solids, include the superconducting determined by measuring the time of flight of sound transition and the superfluid transition. Indeed, one pulses. Recently, a relatively new method, resonant of the most impressive successes in critical phenom- ultrasound spectroscopy (RUS), is being used. In the enahasbeentheuseofacousticstostudythelambda RUSmethod,ratherthanmeasuringsoundvelocities, 2 Acoustics:PhysicalPrinciplesandApplicationstoCondensedMatterPhysics one measures the natural frequencies of elastic vib- in the i-direction is @s =@x, and Newton’s law may ij j ration for a number of normal modes of a sample, be written as and processes these in a computer, along with the shape and mass of the sample. With a proper con- @s @2c ij ¼r i ½3(cid:2) figuration, a single measurement yields enough fre- @x @t2 j quenciestodeterminealloftheelasticconstantsfora material (as many as 21 for a crystal with low sym- where r is the mass density. metry).Samplesmaybepreparedinawidevarietyof The symmetric nature of the definitions, and the shapes,includingrectangular,spherical,etc.,anditis assumption thattheelasticenergymust bequadratic not necessary to orient crystalline samples. A com- in the strains, reduces the number of independent pelling reason for using RUS has to do with the na- elementsofc from81to21.Abasicsymmetryhas ijkl ture of samples of new materials. Whenever a new c invariant if the indices are exchanged in the first ijkl material is developed, initial single crystal samples pairorsecondpairofthefoursubscripts(c ¼c , jikl ijkl are often relatively small, perhaps on the order of a etc.); thus a reduced system of indices may be used: fraction of a millimeter in size. Also, with new 11-1,22-2,33-3,23-4,13-5,12-6,sothat developments in nanotechnology and the possibility c -c . The reduced system is used when tabulat- ijkl mn ofapplicationsinthemicroelectronicsindustry,there ingvaluesofelasticconstants;however,thefullfour- is a great interest in systems which are very small in indextensormustbeusedincalculations.Additional one or more dimensions, such as thin films and one- symmetries of a particular crystal group will reduce dimensional wires. For such small systems, pulse the number of independent elastic constants further measurements are difficult, if not impossible, but below 21; for example, orthorhombic crystals have RUS methods may be readily used. nine independent elastic constants, cubic crystals have three, and isotropic solids have only two. Physical Principlesfor Acoustics in Solids Later, the case of an isotropic elastic solid will be To begin a theory for acoustics in solids, one may useful for the purposes of illustration. In this case, imagine a spring, extended with some initial tension, one has c ¼c ¼c , c ¼c ¼c , c ¼c ¼ 11 22 33 44 55 66 12 13 andconsidertwopointsatpositionsx,andxþdx.If c ¼ c (cid:4)2c , and all other elements of the 23 11 44 one applies an additional local tension, or stress, s, elastic tensor are zero. The two independent elastic then the spring stretches and the two points are dis- constants may be taken as c and c , but other 11 44 placed by c(x), and cðxþdxÞ respectively. The sep- combinations, such as Young’s modulus Y ¼ aration between the twopointswill have changed by c ð3c (cid:4)4c Þ=ðc (cid:4)c Þ and the bulk modulus 44 11 44 11 44 dc, and the fractional change in the separation, de- B¼c (cid:4)4c =3 are also used. The bulk modulus 11 44 fined asthe strain, ise(cid:1)dc=dx. Hooke’s law for the appears in an important thermodynamic identity springtakestheforms¼ce,wherecisaone-dimen- involving g, the ratio of the specific heat at constant sionalelasticconstant.Forathree-dimensionalelastic pressure c to that at constant volume, c : p v solid,onemayuseindices(i,j,etc.)whichcantakeon the values 1, 2, and 3, referring to the x, y, and z c Tb2B g¼ p ¼1þ ½4(cid:2) coordinate directions, and generalize the strain to c rc v p 1(cid:1)@c @c(cid:2) e (cid:1) iþ j ½1(cid:2) Here T is the temperature and b is the thermal ex- ij 2 @x @x j i pansion coefficient (TEC). The symmetric form of e avoids pure rotations, ij Anharmonic Effects which do not involve stress. The stress is generalized to s , a force per unit area acting on a surface ele- The basic formulation of acoustics in solids involves ij ment, where the first index refers to the coordinate theexpansionofenergyminimaaboutequilibriumto directionofacomponentoftheforce,andthesecond second order, or equivalently, assuming a harmonic index refers to the coordinate direction of the unit potential, quadratic in strain. However, there are a normal to the surface element. Hooke’s law becomes numberofeffectswhichrequiregoingbeyondsecond order. Some effects are related to exceeding ‘‘small s ¼c e ½2(cid:2) displacements’’ from equilibrium, such as in quan- ij ijkl kl tum solids with large zero-point motion, and solids where c is the 3(cid:3)3(cid:3)3(cid:3)3 (81 element) elastic at high temperatures (near melting) where thermal ijkl tensor, and where a summation over repeated indices motionsarelarge.Othereffectsoccurinequilibrium is implied. For a small volume element, the net force atnormalorlowtemperatures;theseincludethermal Acoustics:PhysicalPrinciplesandApplicationstoCondensedMatterPhysics 3 expansion, lattice thermal conductivity, and acoustic wave solutions can superimpose and pass through dissipation. oneanotherwithnoeffect.Ananharmonicpotential The relationship between anharmonic effects and allows sound waves (lattice vibrations) to interact thermal expansion is worth discussing. As tempera- andscatterfromoneanother,permittingthetransfer tureisincreased,theamplitudeofatomicoscillations of energy from an ordered to a disordered form increases, or equivalently the occupation of higher (acoustic dissipation), and allowing a change in dis- quantized energy levels increases. If the potential tribution functions in passing from one location to energy was exactly quadratic in displacements, then another (lattice thermal conductivity). the center of oscillation, or the expectation value of Anharmonic effects may be probed with acoustic displacement,wouldremainthesame.Withthesame experiments by measuring the changes in the elastic average positions for the atoms, the system would constants as the sample is subjected to increasing not expand with increasing temperature, and the uniaxial or uniform hydrostatic pressure. The coef- TEC b would be zero. From the thermodynamic ficients which relate the changes to the pressure are identity in eqn [4], one would also have c ¼c . On referred to as ‘‘third-order elastic constants.’’ How p v theotherhand,whenpotentialsareanharmonic,one elastic constants themselves are determined with may have (in the typical case) a stiffer repulsion at acoustic measurements is discussed next. short interatomic distances, and weaker attractive forces at largerdistances. The result is that at higher energy levels, the ‘‘center’’ position between classical Determining ElasticProperties Experimentally turning points moves to larger distances, and the Todeterminethenatureofsoundpropagationinsol- system thermally expands. This situation is illustrat- ids, one must solve eqns [1] through [3] with some ed in Figure 1. specified boundary conditions. Because of the tensor Anharmonicityandthermalexpansioncanalsobe natureoftheequations,therelation betweenparticle readily related to nonlinear acoustics in fluids. For displacement and the direction of wave propagation fluidacoustics,nonlineareffectsareproportionaltoa is quite complicated. To tackle the complexity and dimensionless second order parameter ðr=vÞð@v=@rÞ, make a connection between ultrasound measure- where v is the sound speed, and the derivative is at mentsandtheelasticconstants,twoapproachesmay constantentropy.Forgases,thisparameteris(g(cid:4)1), be taken. The first approach, used in conventional which by the thermodynamic identity in eqn [4], is pulse ultrasound, is to note that if one had a sample proportional to the thermal expansion coefficient b. with a large (infinite) plane surface which is perpen- Thus the absence of nonlinear acoustic effects coin- dicular toone ofthe principleaxesof theelasticten- cides with a vanishing thermal expansion. sor, andif a planewave could belaunched from that That an anharmonic potential results in acoustic surface, then the tensor equations would uncouple, dissipation and lattice thermal conductivity may be and a longitudinal wave or one of two transverse understoodbynotingthatwithaharmonicpotential, wavescouldpropagateindependently.Inthiscase,for onegetsalinearsecond-orderwaveequation,whose each wave, the relationship between the sound velo- city and the independent elastic constants is fairly straightforward.Whilethedeterminationoftheprin- ciple axes and the relationships between the three sound speeds and the relevant elastic constants may be done analytically, the manipulations are compli- catedandmustbedoneonacase-by-casebasis;there y g is no elucidating general formula. The simplest case er Atomic position n ofanisotropicelastic solidwillbepresentedherefor e al purposes of illustration. In this case, Newton’s law enti maybewrittenintermsofthetwoindependentelas- ot P tic constants, c and c : 11 44 d2w r ¼c r2w(cid:4)c =(cid:3)ð=(cid:3)wÞ ½5(cid:2) dt2 11 44 ¼c r2wþðc (cid:4)c Þ=ð=.wÞ ½6(cid:2) 44 11 44 Figure1 Illustrationoftherelationshipbetweenanonquadratic wherethetwoequationsarerelatedbyanidentityfor potential energy curve (and nonlinear acoustics) and the phe- nomenonofthermalexpansion. the = operator. If one has =(cid:3)w¼0, then the first 4 Acoustics:PhysicalPrinciplesandApplicationstoCondensedMatterPhysics equation becomes a simple wave equation for a ExperimentalMethodsforAcousticMeasurements longitudinalwavewithspeedv ¼pfficffiffiffiffiffiffi=ffiffirffiffiffi,andifone in Solids l 11 has =(cid:5) w¼0, then the second equation becomes a Acoustic measurements with the pulse method are simplewaveequationfortransversewaveswithspeed fairly straightforward; emphasis is on careful bond- pffiffiffiffiffiffiffiffiffiffiffiffi v ¼ c =r. t 44 ingoftransducerstosamplesand theuseofsuitable Although the pulse ultrasound method has been high-frequency pulse electronics. The RUS method used extensively in the past, it has a number of di- is less well known, and can be briefly described as sadvantages,includingproblemswithtransducerring- follows. ing,beamdiffraction,andside-wallscattering,andthe In a general RUS measurement, the natural fre- inconvenience that the sample must be recut, repol- quencies of a sample with stress-free boundary con- ished, and reattached to a transducer if one wants ditions are determined by measuring the resonance more than the three elastic constants accessible with frequenciesofthesamplewhenheld(lightly,withno one measurement. The second approach to determi- bonding agents, at two positions on the sample sur- ning elastic constants avoids all of the disadvantages. face) between two transducers. One transducer acts Thesecondapproachistheonedescribedearlieras as a drive to excite vibrations in the sample at a RUS, which involves the use of a computer to nu- tunable frequency, and the second measures the merically solve the elastic constants given a set of amplitude (and possibly the phase) of the response measurednaturalfrequenciesforasolidwithagiven ofthesample;asthefrequencyofthedriveisswept, shape and boundary conditions (usually stress-free asequenceofresonancepeaksmayberecorded.The conditions). The computer processing involves sol- positions of the peaks will determine the natural ving a ‘‘forward problem’’ (finding the natural fre- frequencies f (and hence the elastic constants), and n quencies in terms of the elastic constants) first and the quality factors (Q’s, given by f divided by the n then inverting. Unlike the conventional pulse ultra- full width of a peak at its half-power points) will sound approach, the forward problem does not provide information about the dissipation of elastic provide a simple relationship between the modes of energy. vibrationandtheelasticconstants;thedisplacements RUSmayalsobeusedtomeasurethepropertiesof in the various modes involve all of the elastic con- thin films on a substrate, to determine the effects of stants in a complicated manner, and a numerical induced strain from lattice mismatch, etc. In this computation is required to sort it all out. case, the natural frequencies of the substrate alone The forward problem may be posed as the min- are measured, then the same sample is again meas- imization of a Lagrangian L given by ured with the film in place. From the shifts in the naturalfrequencies,thepropertiesofthefilmmaybe ZZZ L¼ ðro2cc (cid:4)c e e ÞdV ½7(cid:2) determined. i i ijkl ij kl A simple apparatus for making RUS measure- ments is illustrated in Figure 2. In the illustration, a The minimization is accomplished numerically with rectangular parallelepiped sample is supported by a Rayleigh–Ritz method, and the results yield dis- transducers at diametrically opposite corners. Cor- crete resonance frequencies, f ¼2po , given the n n ners are used for contact because they provide elas- elasticconstants,c .FortheRUStechnique,whatis ijkl tically weak coupling to the transducers, greatly needed is the inverse. In most cases, there will be reducing loading, and because the corners are al- more measured frequencies than independent elastic ways elastically active (i.e., they are never nodes), constants; so what is required is to find a set of in- and thus can be used to couple to all of the normal dependent elastic constants which best fits the meas- modes of vibration. ured frequencies, usually in a least squares sense. Furthermore, when there are more measured fre- quencies than independent elastic constants, then Acoustics in Fluids other parameters may be varied in order to best fit the measured frequencies. Such parameters may in- The thermo-hydrodynamic state of a fluid may be clude the shape and dimensions of the sample (al- specified with five fields, which may be taken as the though one known length is necessary), and the massdensityr(r,t),thepressurep(r,t),andthemean orientation of the crystallographic axes relative to flow velocity u(r, t). The five equations needed to the faces of the sample. In any case, it is not neces- determine the five fields are conservation of mass, sary that crystallographic axes be oriented with re- Newton’slawforthemotionofthecenterofmassof specttofacesofasample,althoughcomputationsare afluidelement(threecomponents),andconservation greatly simplified if they are oriented. ofenergyformotionaboutthecenterofmass.These
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