A volume of water in Earth's oceans is, according to Wikipedia, 1 320 000 000 km³.
You could calculate how many drops is that if you could provide any definition of 'drop' unit.
Also, oceans do cover 77% of Earth's surface and the 23% is land.
9.8 m/sec2 or 32.2 ft/sec2 (Both are rounded).
9.81 is the acceleration due to the force of gravity experienced by bodies on or about the surface of the earth (nominally at sea level) the units are meters per second / per second, that is to say a stone dropped from a height will gain 9.81 m/s velocity for every second it falls (is in freefall) however , if you move from the earths surface , this figure will diminish, an example being : if you double your distance from the earths centre you will experience 1/4 of the acceleration (or force) you experienced at the surface
9.81 m/s2 gravity is dependant on the total mass of the two bodies, and the distance between their mass centers, and irrespective of any motion or rotation on earth, their would be a very small acceleration due to rotation about the earths axis (0 at the poles , maximum at the equator) , but this is a totally seperate issue
The surface area of a circle is calculated as Area = pi x radius2. If the radius is in meters, the area will be in square meters.The surface area of a circle is calculated as Area = pi x radius2. If the radius is in meters, the area will be in square meters.The surface area of a circle is calculated as Area = pi x radius2. If the radius is in meters, the area will be in square meters.The surface area of a circle is calculated as Area = pi x radius2. If the radius is in meters, the area will be in square meters.
Ignoring Air Resistance, on earth near the earths surface gravity applies a force on all bodies. The acceleration the ball will experience is -9.8 meters per second per second (i.e. it will slow the ball down. When the ball then falls to the ground from the apogee of the throw it will continue to accelerate at 9.8 meters per second per second per second and will hit the ground at the same speed it left the ground originally. So each second it will slow by 9.8 meters per second. 9.8 meters per second, (or 32.2 feet per second), if the experiment is carried out on or near the surface of the earth. 1.6 meters (5.25 feet) per second, if it's on or near the surface of the moon. 3.52 meters (11.5 feet) per second, if it's on or near the surface of Mars.
The surface area of the sun is about 6.088 X 10 to the 18th meters squared, or the equivalent of 11,900 earths. the sun is made of gases
3 sq meters
The approximate acceleration of a body in freefall near the earths surface due to earths gravitational pull. The object in freefall gains 9.81 meters per second for every second that elapses (ignoring air resistance).
No. Saturn's rings are only 20 meters thick on average.
9.8 m/sec2 or 32.2 ft/sec2 (Both are rounded).
Divide the distance by the time. That will give you the speed in kilometers/hour. Then divide that by 3.6 to convert to meters/second.
"at an altitude of 400 kilometres (250 miles), equivalent to a typical orbit of the Space Shuttle, gravity is still nearly 90% as strong as at the Earth's surface" -- Wikipedia: Earth's gravity # Altitude
A cylinder with a radius of 6 meters and a height of 10.5 meters has a surface area of 622.04m2
A cylinder with a height of 20 meters and a diameter of 10 meters has a surface area of 785.4m2
A cylinder that has a diameter of 10 meters and a height of 3 meters has a surface area of 251.33m2
A cylinder with a height of 10 meters and diameter of 4 meters has a surface area of 150.8m2
The surface area of the pond is measured in square meters.