frame-dragging

The effects of frame-dragging are slightly too small to be measured by such an experiment.

Relativistic jets may provide evidence for the reality of frame-dragging.

This process is known as the Lense-Thirring effect or frame-dragging.

Another, which is related to rotating masses, is called frame-dragging.

It describes various theoretical and experimental/observational aspects of frame-dragging.

Caused by the general relativity effect of frame-dragging on a gyroscope orbiting a spinning body.

The mission plans were to test two unverified predictions of general relativity: the geodetic effect and frame-dragging.

Under general relativity, the acceleration of a body in a straight line causes light to drag, in an effect known as frame-dragging.

Qualitatively, frame-dragging can be viewed as the gravitational analog of electromagnetic induction.

It is a gravitomagnetic frame-dragging effect.

In the ringdown phase of a Kerr black hole, frame-dragging produces a gravitation wave with the horizon frequency.

It was also found that, as our planet rotates, it drags space-time with it – a phenomenon known as frame-dragging.

In the context of General Relativity, the democratic principle allows quick, order-of-magnitude calculations for the strength of gravitomagnetic effects such as frame-dragging.

Route-dependence due to frame-dragging may come into play, which would invalidate this idea and complicate the process of determining globally agreed differences in underlying clock rate.

The Gravity Probe B satellite, launched in 2004 and operated until 2005, detected frame-dragging and the geodetic effect.

However, as seen above, frame-dragging occurs about every rotating mass and at every radius r and colatitude θ, not only within the ergosphere.

In polar orbit, with the gyro spin directions also pointing toward HR8703, the frame-dragging and geodetic effects came out at right angles, each gyroscope measuring both.

Frame-dragging removes the usual distinction between accelerated frames (which show gravitational effects) and inertial frames (where the geometry is supposedly free from gravitational fields).

Frame-dragging is an effect on spacetime, predicted by Einstein's general theory of relativity, that is due to non-static stationary distributions of mass-energy.

Rotational frame-dragging (the Lense-Thirring effect) appears in the general principle of relativity and similar theories in the vicinity of rotating massive objects.

Everitt is Principal Investigator of the Gravity Probe B mission mainly aimed to test frame-dragging at an expected accuracy of 1%.

In particular, precession due to general relativistic frame-dragging should be greater for HD 15082b than for Mercury, where it is so far too small to have been observed.

Both the frame-dragging and geodetic precession effects are so small that they require near-perfection in the design and construction of the instrument, Gravity Probe B (or GP-B).

Measure the orbital frame-dragging, known also as Lense-Thirring precession caused by the angular momentum of Jupiter, and possibly a new test of general relativity effects connected with the Jovian rotation.

As the neutron star loses angular velocity due to frame-dragging and by the bleeding off of energy due to it being a rotating magnetic dipole, the crust develops an enormous amount of stress.