Laws and Models: Science, Engineering, and TechnologyThe "laws" that govern our physical universe come in many guises-as principles, theorems, canons, equations, axioms, models, and so forth. They may be empirical, statistical, or theoretical, their names may reflect the person who first expressed them, the person who publicized them, or they might simply describe a phenomenon. However they may be named, the discovery and application of physical laws have formed the backbone of the sciences for 3,000 years. They exist by thousands. Laws and Models: Science, Engineering, and Technology-the fruit of almost 40 years of collection and research-compiles more than 1,200 of the laws and models most frequently encountered and used by engineers and technologists. The result is a collection as fascinating as it is useful. Each entry consists of a statement of the law or model, its date of origin, a one-line biography of the people involved in its formulation, sources of information about the law, and cross-references. Illustrated and highly readable, this book offers a unique presentation of the vast and rich collection of laws that rule our universe. Everyone with an interest in the inner workings of nature-from engineers to students, from teachers to journalists-will find Laws and Models to be not only a handy reference, but an engaging volume to read and browse. |
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... material is quoted with permission , and sources are indicated . A wide variety of references are listed ... materials or for the consequences of their use . The consent of CRC Press LLC does not extend to copying for general ...
... material is quoted with permission , and sources are indicated . A wide variety of references are listed ... materials or for the consequences of their use . The consent of CRC Press LLC does not extend to copying for general ...
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... material models .. Wagner ......... Wave motion . Yoda power law . Young - Helmholtz Young modulus . .395 .429 .434 .438 .442 445 .452 .454 .455 .467 470 476 .480 .493 494 495 AAAS ACS AGI AICHE AIME AIP AMA actual mechanical advantage ...
... material models .. Wagner ......... Wave motion . Yoda power law . Young - Helmholtz Young modulus . .395 .429 .434 .438 .442 445 .452 .454 .455 .467 470 476 .480 .493 494 495 AAAS ACS AGI AICHE AIME AIP AMA actual mechanical advantage ...
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... materials . Keywords : binary , heterogeneous , materials , multicomponent , phase Source : Bever , M. B. 1986 . ADRIAN LAW ; ADRIAN - BRONK , LAW OF SEE ALL - OR - NONE ADSORPTION LAW — SEE FREUNDLICH ADSORPTION ISOTHERM MODELS — SEE ...
... materials . Keywords : binary , heterogeneous , materials , multicomponent , phase Source : Bever , M. B. 1986 . ADRIAN LAW ; ADRIAN - BRONK , LAW OF SEE ALL - OR - NONE ADSORPTION LAW — SEE FREUNDLICH ADSORPTION ISOTHERM MODELS — SEE ...
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... material , often applicable to many metals and plastics , is proportional to the one - third power of time , t : 1/3 ... material are the same as the wavelengths given off by the material when luminous . Angstrom measured the wavelength ...
... material , often applicable to many metals and plastics , is proportional to the one - third power of time , t : 1/3 ... material are the same as the wavelengths given off by the material when luminous . Angstrom measured the wavelength ...
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... material are dependent on the speed of testing , which with steel the tensile strength was less with a slower speed , because of the irregular vibrations of the atoms of the material . Bach law is a power law modification of Hooke law ...
... material are dependent on the speed of testing , which with steel the tensile strength was less with a slower speed , because of the irregular vibrations of the atoms of the material . Bach law is a power law modification of Hooke law ...
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Common terms and phrases
absolute temperature American physicist angle Asimov atomic Ballentyne Besancon body Boltzmann constant Bolz Bothamley characteristic length chemical chemist Sources chemistry coefficient CONSERVATION Considine constant crystal D. W. G. and Lovett Daintith diffusivity dimensionless group effect elastic electric electron Encyclopedia energy engineer Sources English physicist equation equilibrium flow fluid force French physicist frequency Friel gases German American German physicist Sources Gillispie gravity heat transfer Honig Isaacs Keywords Landau Lapedes LARGE NUMBERS LAW OF-SEE LAW-SEE light liquid Mandel mass density mass transfer material mathematics molecular molecules Morris nerve NEWTON Nobel prize NUSSELT Parker particle physical chemist physicist Sources physics Sources physiologist physiologist Sources Potter POWER LAW PRANDTL pressure proportional R. C. and James R. E. and Tuve radiation ratio reaction relates relationship represented Reynolds number Science solution specific heat Stedman stress surface thermal thermodynamics Thewlis twentieth century vapor velocity volume wavelength York Young modulus
Popular passages
Page 343 - Pressure exerted anywhere upon a mass of liquid is transmitted undiminished in all directions, and acts with the same force on all equal surfaces, and in a direction at right angles to those surfaces.
Page 275 - The logarithm of a quotient is equal to the logarithm of the dividend minus the logarithm of the divisor. , M , ,• , . logi — = log
Page 275 - The logarithm of a root of a number is equal to the logarithm of the number divided by the index of the root.
Page 4 - The total pressure exerted by a mixture of gases is equal to the sum of the partial pressures of the gases in the mixture.
Page 243 - The cubes of the mean distances of the planets from the sun are proportional to the squares of their times of revolution about the sun.
Page 14 - Archimedes stated that a body immersed in a fluid is buoyed up by a force equal to the weight of the displaced fluid.
Page 275 - The logarithm of a power of a number is equal to the logarithm of the number multiplied by the exponent of the power. log» Np = p log
Page 267 - The volume of a gas mixture is equal to the sum of the volumes that would be occupied by each of the components of the mixture if at the temperature and pressure of the mixture.
Page 322 - Every particle of matter, in the universe, attracts every other particle with a force, which is directly proportional to the product of their masses and inversely proportional to the square of the distance between them.