Exploring Inertia & Acceleration in Space & Universe

In summary, the question of whether inertial forces can result from the acceleration of space itself is not addressed by the General Relativity theory. This is because General Relativity does not incorporate the concept of Mach's principle, which makes assumptions that are not consistent with the framework of GR. Additionally, some versions of Mach's principle are ruled out by GR, such as the assumption that the universe cannot have a non-zero total angular momentum.
  • #1
Shaw
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I'm curious to know if General Relativity theory has an answer to this question:

Space is not an abstract concept (it has volume and contains energy), so if an observer cannot tell if he is accelerating and the Universe is at rest, or if he is at rest and the Universe is accelerating (corollary to Mach's observation on velocity), then can one also say that if inertial forces result from acceleration in space, can they conceivably also result from the acceleration of space itself?
 
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  • #2
Einstein was convinced that this would be the case - if a mass were somehow retained in some absolute location and the entire universe accelerated relative to the mass, then the stationary mass would experience the same reactionary force as if it were accelerated
relative to space.
 
  • #3
Shaw said:
I'm curious to know if General Relativity theory has an answer to this question:

Space is not an abstract concept (it has volume and contains energy), so if an observer cannot tell if he is accelerating and the Universe is at rest, or if he is at rest and the Universe is accelerating (corollary to Mach's observation on velocity), then can one also say that if inertial forces result from acceleration in space, can they conceivably also result from the acceleration of space itself?

The problem is that an observer can tell if he is accelerating.

Mach's principle is not a part of General Relativity, so I would say that your question doesn't have an answer in the framework of GR, because it makes assumptions that are not part of the framework of GR. In fact, some versions of Mach's principle are ruled out by GR. You'd have to be a bit more specific about your statement of Mach's principle for me to tell if your interpreation of it is one of those that's inconsitent with GR or not.

The usual failulre of Mach's principle occurs with is a rotating universe - GR allows the universe to have a non-zero total angular momentum, many interpretations of Mach's principle don't allow this.
 

FAQ: Exploring Inertia & Acceleration in Space & Universe

What is inertia and how does it relate to space and the universe?

Inertia is the tendency of an object to resist changes in its motion. In space and the universe, the lack of gravitational forces and friction means that objects will continue moving in a straight line at a constant speed unless acted upon by an external force. This is known as Newton's first law of motion.

How does acceleration work in space and the universe?

In space and the universe, acceleration is caused by the presence of gravitational forces. Objects with mass will accelerate towards each other due to the force of gravity. The strength of the gravitational force depends on the mass of the objects and the distance between them. Acceleration can also occur due to the presence of other forces, such as thrust from a rocket or the pull of a planet's gravity on a satellite.

How do scientists study inertia and acceleration in space and the universe?

Scientists use a variety of methods and tools to study inertia and acceleration in space and the universe. These include spacecraft and satellites equipped with sensors and instruments that can measure and record changes in motion, as well as mathematical models and simulations to help understand and predict the behavior of objects in space.

What are some real-life applications of understanding inertia and acceleration in space and the universe?

Understanding inertia and acceleration in space and the universe has many practical applications. For example, it is crucial for spacecraft navigation and control, as well as for predicting the motion of celestial bodies such as planets, moons, and comets. It also helps us understand the formation and evolution of the universe and its various objects, such as stars and galaxies.

How does the concept of inertia and acceleration in space and the universe tie into the laws of physics?

Inertia and acceleration are fundamental concepts in the laws of physics. They are closely related to Newton's laws of motion, which describe the behavior of objects in the presence of forces. Inertia and acceleration also play a crucial role in other areas of physics, such as the theory of relativity and the study of gravity and cosmology.

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