{g represents gravity, which is not a speed and thus cannot be used in calculating rate of acceleration.} ^This incorrect, g IS an acceleration. 1g is 9.8 m/s^2.
That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.That would be the escape velocity of Earth, about 11.2 km/sec. I am assuming that the object falls from far, far away, and that air resistance is negligible.
It would be convenient to specify which of Earth's movements you are talking about. In the yearly movement around the Sun, Earth moves at a rate of 30 km per second.
The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.The escape velocity from Earth is 11.2 kilometers/second. This is also the speed that an object would reach if it fell onto Earth's surface from far, far away ("infinity" is often used, to simplify calculations) - without air resistance, and without interference by other objects that might also attract it.
About 10700000000000000000000000 h bombsThis is a complicated function of:yieldslocations of burstsmaterial around burstsetc.It would be far far easier to just blow away the atmosphere and leave the earth alone and even far far easier to light firestorms in all the forests and fill the stratosphere with soot for decades causing nuclear winter.
Neither, effects would be mostly localized to 1000 mile area targeted. Effects of fallout radiation is unpredictable though due to weather, mostly wind and precipitation. Earth is far bigger.
A "light year" is a measure of distance, derived from "how far light can travel in one Earth year". Thus, if you shine a torch for the amount of time it takes the Earth to orbit the sun exactly once, that light would have travelled the distance of a "light year".
365 , and in a Leap Year 366.
One day on Pluto is roughly 6.4 Earth days. A year is about 248.5 Earth years. Earth will become like this Also very cold that cannot survive man
It depends on the crust....
Every Year as far as humanity remembers. Its one of the oldest religions on earth.
if it was close like mercury to the sun everything would burn up and it would take 88 earth days to go around the sun. if the earth was as far as pluto(dwarf planet)the earth would freeze up and it would take 258 earth years
No estoy segura
If you got that far I am almost 50% sure it would be about 2,259km
If the earth moves from its orbit, might be it will be permanently dark to earth till we reaches the another solar system.
It is because Earth is near to the Sun and Jupiter is far so when Earth turns 11 turns (years) it will be 1 year in Jupiter...
6 planets and the lengh of a year is 29 years of earth
As far as records go, 1922.