Introductory Nuclear PhysicsA comprehensive, unified treatment of present-day nuclear physics-the fresh edition of a classic text/reference. "A fine and thoroughly up-to-date textbook on nuclear physics . . . most welcome." -Physics Today (on the First Edition). What sets Introductory Nuclear Physics apart from other books on the subject is its presentation of nuclear physics as an integral part of modern physics. Placing the discipline within a broad historical and scientific context, it makes important connections to other fields such as elementary particle physics and astrophysics. Now fully revised and updated, this Second Edition explores the changing directions in nuclear physics, emphasizing new developments and current research-from superdeformation to quark-gluon plasma. Author Samuel S.M. Wong preserves those areas that established the First Edition as a standard text in university physics departments, focusing on what is exciting about the discipline and providing a concise, thorough, and accessible treatment of the fundamental aspects of nuclear properties. In this new edition, Professor Wong: * Includes a chapter on heavy-ion reactions-from high-spin states to quark-gluon plasma * Adds a new chapter on nuclear astrophysics * Relates observed nuclear properties to the underlying nuclear interaction and the symmetry principles governing subatomic particles * Regroups material and appendices to make the text easier to use * Lists Internet links to essential databases and research projects * Features end-of-chapter exercises using real-world data. Introductory Nuclear Physics, Second Edition is an ideal text for courses in nuclear physics at the senior undergraduate or first-year graduate level. It is also an important resource for scientists and engineers working with nuclei, for astrophysicists and particle physicists, and for anyone wishing to learn more about trends in the field. |
Contents
I | 1 |
III | 4 |
IV | 7 |
V | 18 |
VI | 21 |
VIII | 25 |
IX | 27 |
X | 30 |
XXXVIII | 161 |
XXXIX | 165 |
XL | 168 |
XLI | 178 |
XLII | 181 |
XLIII | 189 |
XLIV | 205 |
XLVI | 212 |
XI | 32 |
XII | 35 |
XIII | 39 |
XIV | 48 |
XV | 53 |
XVI | 57 |
XVII | 61 |
XVIII | 65 |
XIX | 68 |
XX | 71 |
XXI | 78 |
XXII | 80 |
XXIII | 89 |
XXIV | 95 |
XXV | 105 |
XXVII | 109 |
XXVIII | 113 |
XXIX | 115 |
XXX | 119 |
XXXI | 124 |
XXXII | 129 |
XXXIII | 132 |
XXXIV | 139 |
XXXV | 143 |
XXXVI | 150 |
XXXVII | 154 |
XLVII | 218 |
XLVIII | 229 |
XLIX | 235 |
L | 238 |
LI | 246 |
LII | 250 |
LIII | 256 |
LIV | 271 |
LV | 275 |
LVII | 280 |
LVIII | 286 |
LIX | 291 |
LX | 303 |
LXI | 308 |
LXII | 317 |
LXIV | 326 |
LXV | 340 |
LXVI | 355 |
LXVIII | 361 |
LXIX | 363 |
LXX | 366 |
LXXI | 373 |
LXXII | 381 |
LXXIII | 389 |
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Common terms and phrases
a-particle antiquarks antisymmetric atom band baryon binding energy calculation coefficients Coulomb coupling d-quarks decay deformation density dependence deuteron electromagnetic electron emitted equation example excitation energy expectation value expressed Fermi fission given in Eq ground hadrons Hamiltonian heavy nuclei incident intrinsic spin involved isospin kinetic energy lepton magnetic dipole magnetic dipole moment many-body mass matrix element measured mesons multipole neutrinos neutrons and protons nuclear force nuclear physics nuclear structure nucleon number nucleon-nucleon interaction nucleons nucleus observed obtained operator optical model potential orbital angular momentum pair parameters parity particle phase shifts pions possible projectile proton proton number quadrupole quantity quantum number quarks radial radius reaction reason relation result rotational scattering amplitude scattering cross section shell shown in Fig space spherical harmonics spherical tensor ẞ-decay star strong interaction symmetry target nucleus transition probability two-body vector wave function weak interaction y-rays
