Gravity determines the weight of an object. This is different from mass which stays constant regardless of gravitational pull. This explains why astronauts become "weightless" in outer space even though there mass is the same.
The factors that determine the gravitational potential energy of an object are its mass, the acceleration due to gravity, and its height above a reference point. The gravitational potential energy of an object increases with mass, height, and strength of gravity.
The shape and center of gravity of an object are key factors that determine its stability. Objects with a wider base and lower center of gravity are usually more stable because they are less likely to tip over.
To determine the vertical velocity of an object, you can use the formula: vertical velocity initial vertical velocity (acceleration due to gravity x time). This formula takes into account the object's initial velocity and how gravity affects its motion over time.
The centre of gravity does not, by itself, determine whether an object is at rest or in motion. The location of the centre of gravity, relative to where the object is supported, can contribute one of many forces that can act on the object. And it is is the [vector] sum of these forces which determines whether the object remains at rest or in uniform motion.
Measuring the force of gravity acting on an object involves quantifying the pull that Earth's gravity exerts on the object. This is typically done using a scale or a balance to determine the object's weight, which is a measure of the gravitational force acting on it. Weight is directly proportional to the force of gravity.
Volume, density, and gravity.
by size,volume and gravity
When you weigh yourself, the force of gravity is pulling you down to the scale. Therefore weight is determined by gravity.
The factors that determine the gravitational potential energy of an object are its mass, the acceleration due to gravity, and its height above a reference point. The gravitational potential energy of an object increases with mass, height, and strength of gravity.
that's a difficult one but wait have you hear of earth rotation that maintains gravity.
The shape and center of gravity of an object are key factors that determine its stability. Objects with a wider base and lower center of gravity are usually more stable because they are less likely to tip over.
To determine the vertical velocity of an object, you can use the formula: vertical velocity initial vertical velocity (acceleration due to gravity x time). This formula takes into account the object's initial velocity and how gravity affects its motion over time.
The centre of gravity does not, by itself, determine whether an object is at rest or in motion. The location of the centre of gravity, relative to where the object is supported, can contribute one of many forces that can act on the object. And it is is the [vector] sum of these forces which determines whether the object remains at rest or in uniform motion.
Measuring the force of gravity acting on an object involves quantifying the pull that Earth's gravity exerts on the object. This is typically done using a scale or a balance to determine the object's weight, which is a measure of the gravitational force acting on it. Weight is directly proportional to the force of gravity.
The center of gravity of an irregular object can be determined by finding the point where the object would balance perfectly in any orientation. This can be done by supporting the object at different points and adjusting until it is balanced. The center of gravity is typically the point where all these balancing points intersect.
Buoyancy and pressure determine whether the object floats or sinks.
The force of gravity between any two objects depends on the mass of the first object and the distance of the second object.