Einstein's Other Theory

Name: Einstein's Other Theory
Brand: Princeton University Press
SKU: 9780691118260
Price: 84.99 EUR
Availability: InStock

★★★★★

€84.99

Product variants

A01=Donald W. Rogers

Author_Donald W. Rogers

Avogadro constant

Black body

Black-body radiation

Bohr model

Bolometer

Boltzmann distribution

Bose-Einstein condensate

Bose-Einstein statistics

Boson

Category=PHH

Cooper pair

Cryogenics

Debye frequency

Debye model

Degrees of freedom (mechanics)

Dirac delta function

Einstein field equations

Electron magnetic moment

Emissivity

Energy density

Energy level

eq_bestseller

eq_isMigrated=1

eq_isMigrated=2

eq_nobargain

eq_non-fiction

eq_science

Equivalence principle

Exchange interaction

Excited state

Fermi-Dirac statistics

Fermion

Ground state

Harmonic oscillator

Heat capacity

Ideal gas

Lambda point

Laser

Magnetic trap (atoms)

Molecular vibration

Monatomic gas

Neutron

Number density

Overtone

Partition function (statistical mechanics)

Phase transition

Phonon

Photon

Photon gas

Planck constant

Population inversion

Probability

Quantum harmonic oscillator

Quantum mechanics

Quantum number

Radiation pressure

Real gas

Refractive index

Resonance

Stefan-Boltzmann constant

Stimulated emission

Superconductivity

Temperature

Thermal energy

Thermal equilibrium

Thermal radiation

Threshold energy

Units of energy

Vapor

Vibration

Wave equation

Wave function

Wavelength

Wavenumber

Weak interaction

Wien's displacement law

Zero-point energy

Product details

ISBN 9780691118260
Weight: 425g
Dimensions: 152 x 235mm
Publication Date: 14 Mar 2005
Publisher: Princeton University Press
Publication City/Country: US
Product Form: Hardback

Delivery/Collection within 10-20 working days

Our Delivery Time Frames Explained
2-4 Working Days: Available in-stock

10-20 Working Days: On Backorder

Will Deliver When Available: On Pre-Order or Reprinting

We ship your order once all items have arrived at our warehouse and are processed. Need those 2-4 day shipping items sooner? Just place a separate order for them!

Einstein's theories of relativity piqued public curiosity more than any other mathematical concepts since the time of Isaac Newton. Scientists and non-scientists alike struggled, not so much to grasp as to believe the weird predictions of relativity theory--shrinking space ships, bending light beams, and the like. People all over the world watched with fascination as Einstein's predictions were relentlessly and unequivocally verified by a hundred experiments and astronomical observations. In the last decade of the twentieth-century, another of Einstein's theories has produced results that are every bit as startling as the space-time contractions of relativity theory. This book addresses his other great theory, that of heat capacity and the Bose-Einstein condensate. In doing so, it traces the history of radiation and heat capacity theory from the mid-19th century to the present. It describes early attempts to understand heat and light radiation and proceeds through the theory of the heat capacity of solids. It arrives at the theory of superconductivity and superfluidity--the astonishing property of some liquids to crawl spontaneously up and out of their containers, and the ability of some gases to cause light to pause and take a moment's rest from its inexorable flight forward in time. Couched in the terminology of traditional physical chemistry, this book is accessible to chemists, engineers, materials scientists, mathematicians, mathematical biologists, indeed to anyone with a command of first-year calculus. In course work, it is a collateral text to third semester or advanced physical chemistry, introductory statistical mechanics, statistical thermodynamics, or introductory quantum chemistry. The book connects with mainstream physical chemistry by treating boson and fermion influences in molecular spectroscopy, statistical thermodynamics, molecular energetics, entropy, heat capacities (especially of metals), superconductivity, and superfluidity.

Donald W. Rogers is Professor Emeritus at Long Island University. He has published in the "Journal of Physical Chemistry", the "Journal of The American Chemical Society", and elsewhere. His research in quantum thermodynamics is currently supported by the National Science Foundation through the National Center for Supercomputing Applications.