Baltimore Lectures on Molecular Dynamics and the Wave Theory of LightCUP Archive, 1904 - 694 pàgines |
Continguts
The wave theory of light molecular treatment by Fresnel | 5 |
Direction of the vibrations in polarized light Dynamical theory | 14 |
LECTURE II | 22 |
PART II | 28 |
Molecular Variations of complex serial molecule Continued fraction to | 38 |
LECTURE V | 52 |
LECTURE VI | 61 |
Molecular Vibrations of serial molecule Lagrange algorithm of finite | 69 |
Formulas expressing chiral inertia in wavemotion given also | 445 |
Diagrams to illustrate motion of incompressible elastic solid | 450 |
Molecular Electroetherial theory of the velocity of light through transparent | 461 |
APPENDIX | 468 |
Kinetic energy of the ether within a moving atom extra inertia | 485 |
The motion of ponderable matter through ether | 486 |
WaterstonianMaxwellian distribution of energies | 493 |
Dynamical testcases for the B M doctrine reflections of ball | 504 |
Molar Solutions for distortional waves Rotational oscillation in origin | 80 |
Molecular Sudden and gradual commencements of vibration fluorescence | 90 |
LECTURE X | 108 |
Molecular Difficulties regarding polarization by reflection double refraction | 117 |
Molecular Mutual force between atom and ether Vibrating molecule | 150 |
Molar | 155 |
Molecular Application of Sellmeiers dynamical theory to the dark lines | 176 |
dispersion by prisms of sodiumvapour by Henri Becquerel | 185 |
Molar Rates of transmitting energy outwards by the two waves 211214 | 211 |
Molar Thlipsinomic treatment of compressibility Double refraction | 221 |
176184 | 260 |
LECTURE XVII | 279 |
Molecular Vibrations of polarized light are perpendicular to plane of polari | 323 |
Mathematical investigation of spherical waves in elastic solid | 336 |
Molar Errors in construction of Fresnels rhomb determined | 393 |
Ether is gravitationless matter filling all space Total amount | 401 |
LECTURE XIX | 408 |
Molar Dynamical theory of adamantinism imaginary velocity of con | 415 |
Simplification of waves at great distance from origin | 434 |
Statistics of reflections from corrugated boundary marlin spike | 512 |
doctrine applied to the equilibrium of a tall column of | 524 |
of ponderable matter in the space known to astronomers | 532 |
APPENDIX | 541 |
Stable equilibrium of several electrions in an atom Exhaustion | 551 |
Electrionic explanation of pyroelectricity and piezoelectricity | 559 |
APPENDIX | 569 |
Interior melting of ice James Thomsons physical theory | 579 |
APPENDIX | 584 |
The influence of frictionless wind on waves in friction | 590 |
Waves under motive power of gravity and cohesion | 598 |
How to draw partitional boundary in three dimensions parti | 611 |
Different qualities on two parallel sides of a crystal oppositely | 622 |
Ternary tactics in lateral and terminal faces of quartz | 637 |
APPENDIX I | 643 |
Single assemblage in simple cubic order Equilateral assemblage | 661 |
Stabilities of monatomic and diatomic assemblages stability | 671 |
APPENDIX | 679 |
APPENDIX L | 688 |
Frases i termes més freqüents
according amplitude angle of incidence atoms axis centimetre centre chiral coefficients components condensational-rarefactional waves crystal cubic cubic centimetre Curve denote density diagram direction displacement distance distortion double refraction dx dy dy dz dynamical elastic solid electrions equal equations equivoluminal explained force formula Fresnel's rhomb gases give Green Hence homogeneous incident light inertia infinitely isotropic Lecture line of vibration liquid Lord Rayleigh luminiferous ether mass medium metals Molar Molecular molecular dynamics molecules motion negative parallel particles period phasal plane of incidence ponderable matter positive Principal Incidence propagational velocity radius ratio Rayleigh reflected light refractive index respect result rigidity simple harmonic motion small in comparison solution space spherical Stokes suppose supposition surface theory of light transparent values velocity of propagation velocity potential vibrational lines vibrations vibrations perpendicular wave-length wave-plane wave-surface zero