Of Time and Space and Other Things |
From inside the book
Results 1-3 of 21
Page 88
... According to Coulomb , the electromagnetic force between the two objects would be expressed by the following equation : Fe == qq ' d2 ( Equation 3 ) where q is the charge on one object , q 888 OF TIME AND SPACE AND OTHER THINGS.
... According to Coulomb , the electromagnetic force between the two objects would be expressed by the following equation : Fe == qq ' d2 ( Equation 3 ) where q is the charge on one object , q 888 OF TIME AND SPACE AND OTHER THINGS.
Page 89
... objects separated by one centi- meter , center to center , each object possessing identical charge ( positive in one case and negative in the other ) and identical mass ( no qualifications ) . There is both a gravitational and an ...
... objects separated by one centi- meter , center to center , each object possessing identical charge ( positive in one case and negative in the other ) and identical mass ( no qualifications ) . There is both a gravitational and an ...
Page 91
... object with no charge , what about an object with maximum charge ? If we are going to make charge maximum , let's first eliminate neutral particles which add mass without charge . Let's suppose , instead , that we have a piece of matter ...
... object with no charge , what about an object with maximum charge ? If we are going to make charge maximum , let's first eliminate neutral particles which add mass without charge . Let's suppose , instead , that we have a piece of matter ...
Contents
A Galaxy at a Time | 109 |
Forget It | 122 |
Nothing Counts | 134 |
Copyright | |
4 other sections not shown
Other editions - View all
Common terms and phrases
ancient astronomer atoms attraction average Babylonian begin body calculated calendar called calorie catalyst celestial equator centimeters century chemical cm²/sec² consider constellation diameter discovered distance dyne Earth eclipse ecliptic electric charge electromagnetic force electrons energy equal fact five fluorine frequency galaxy gram gravitational force Greek Gregorian calendar heartbeat hundred hydrogen inert gases instance joule Julian Julian calendar Jupiter latitude light light-years live longitude Mars mass means measure meridian miles million minutes molecules Moon move Neptune night sky nucleus object observer Olbers orbit oxygen particles physicist Planck Planck's constant planet planetoids platinum Pole positrons pre-supernova radiation ratio reason represent Roche limit Roman numerals rotation Saturn shared pool shell sidereal day solar day Solar System stars sulfur sulfur dioxide supernova suppose sure surface symbols temperature thousand tion true satellite tug-of-war value turned units universe Uranus Venus vernal equinox visible xenon