The discussion revolves around the measurement of gravity in specific areas of space, particularly the concept of measuring gravity without referencing the force exerted on another object. Participants explore various methods and definitions related to gravity, including its measurement at different altitudes above Earth.
Participants express differing views on whether gravity can be measured independently of other masses, leading to an unresolved debate on the nature of gravity and its measurement. There is no consensus on the methods or definitions discussed.
Some limitations are noted regarding the methods of measurement, such as the dependence on the presence of other masses and the challenges in achieving absolute measurements with clock-based methods.
nuby said:Not force on another object, but some "unit" or measure of gravity itself.
Davenuby said:But is there a way to measure gravity in a particular area of space, or a "measurement" .. I.E. the gravity 10 miles above Earth v.s 1000 miles above
Well, there is the "g", which is equal to the acceleration due to gravity at the surface of the Earth. It is defined as 9.80665 m/s^2, and doesn't rely on the mass of the object being accelerated. Thus the strength of gravity at an altitude equal to the radius of the Earth would be 0.25gnuby said:Why can't an object's gravity be measured without comparing it to another object (edited)? It's a physical property that exists in space, no?
Gravity is defined to be a force on another object, so if you aren't measuring the force on another object you aren't measuring gravity.nuby said:...Not force on another object, but some "unit" or measure of gravity itself.
We can't, because a photon doesn't have a trajectory. But that's a quibble because you might as reasonably ask about a flash of light, and a flash of light does have a position and a trajectory.nuby said:How would one calculate the trajectory of a photon around a planet/star?
nuby said:It's a physical property that exists in space, no?
I think you might be thinking of gravity as some kind of "gravitational field" with some "gravity measure" in just the same way that electric fields seem to work.nuby said:It's a physical property that exists in space, no?
The practicalities of the basic measurement are also of interest - before we get to 'light', I think. You could drop a heavy object and plot its change in height above the ground with time. That would give you the acceleration towards the Earth (= local g). You could 'weigh' a standard mass whilst in an aeroplane but then you would need to measure / monitor the altitude of the plane to keep its altitude constant. More than 10 miles would be a difficult / inconvenient. Once you have a orbit, you are back in business.nuby said:But is there a way to measure gravity in a particular area of space, or a "measurement" .
Newton 3 requires that there is a force on the Earth, too. (And on all other masses in the Solar System / Universe). But Relativity tells us that everything is relative to 'other objects'. All the thought experiments about people in lifts (elevators) tell us that they can only tell there's any acceleration involved when there's a difference between the lift and the passenger.nuby said:Not force on another object,
I think we are making this unnecessarily complicated. There are standard methods of measuring gravity, which are used in oil and gas exploration. https://en.m.wikipedia.org/wiki/Gravimetrynuby said:Dumb question probably -- But is there a way to measure gravity in a particular area of space, or a "measurement" .. I.E. the gravity 10 miles above Earth v.s 1000 miles above. Not force on another object, but some "unit" or measure of gravity itself.
Nugatory said:Gravity is defined to be a force on another object, so if you aren't measuring the force on another object you aren't measuring gravity.
But this method requires knowledge about the gravity field beyond that which can be measured by the clocks. For example, if we place our clocks in a sealed room in an unknown gravity field, the clocks can only give us the potential difference between the clocks, but not the difference in gravity experienced by the clocks. You can have the same potential difference between the clocks when gravity varies very little from the average from top to bottom of the room, as when the difference varies by more. In these two cases, the difference in tick rates for the clocks can be the same, while the difference in gravitational force between each pair of clocks is not.f95toli said:Not quite true. You can also measure gravity by using an (or rather two)( accurate clocks (i.e. using GR).
There have been a number of demonstration where people have done this using optical clocks and I am aware of projects where people are trying to develop this into a commercially viable method, right now the equipment is too bulky and too expensive. In reality you would probably also measure the difference between two different clocks; i.e. it would not quite be an "absolute" measurement.
See e.g.
Grotti, Jacopo, et al. "Geodesy and metrology with a transportable optical clock." Nature Physics (2018): 1.
Right. Dividing by the known distance between the clocks, they give you the proper acceleration of the room. i.e. the local acceleration of gravity. If one is using a pair of clocks as a gravimeter, this is the piece of information you are looking for.Janus said:the clocks can only give us the potential difference between the clocks, but not the difference in gravity experienced by the clocks