Radius of gyration

The radius of gyration or gyradius of a body about the axis of rotation is defined as the radial distance to a point which would have a moment of inertia the same as the body's actual distribution of mass, if the total mass of the body were concentrated there.

The radius of gyration has dimensions of distance [L] or [M0LT0] and the SI unit is the metre (m).

Mathematically the radius of gyration is the root mean square distance of the object's parts from either its center of mass or a given axis, depending on the relevant application.

It is actually the perpendicular distance from point mass to the axis of rotation.

One can represent a trajectory of a moving point as a body.

Then radius of gyration can be used to characterize the typical distance travelled by this point.

be their perpendicular distances from the axis of rotation.

being the total mass of the body), From the above equations, we have Radius of gyration is the root mean square distance of particles from axis formula

Therefore, the radius of gyration of a body about a given axis may also be defined as the root mean square distance of the various particles of the body from the axis of rotation.

It is also known as a measure of the way in which the mass of a rotating rigid body is distributed about its axis of rotation.Radius of gyration (in polymer science)(

[1] In structural engineering, the two-dimensional radius of gyration is used to describe the distribution of cross sectional area in a column around its centroidal axis with the mass of the body.

The gyration radius is useful in estimating the stiffness of a column.

If the principal moments of the two-dimensional gyration tensor are not equal, the column will tend to buckle around the axis with the smaller principal moment.

For example, a column with an elliptical cross-section will tend to buckle in the direction of the smaller semiaxis.

In engineering, where continuous bodies of matter are generally the objects of study, the radius of gyration is usually calculated as an integral.

) can be calculated in terms of the mass moment of inertia

The radius of gyration of an individual homopolymer with degree of polymerization N at a given time is defined as:[3] where

As detailed below, the radius of gyration is also proportional to the root mean square distance between the monomers: As a third method, the radius of gyration can also be computed by summing the principal moments of the gyration tensor.

Since the chain conformations of a polymer sample are quasi infinite in number and constantly change over time, the "radius of gyration" discussed in polymer physics must usually be understood as a mean over all polymer molecules of the sample and over time.

That is, the radius of gyration which is measured as an average over time or ensemble: where the angular brackets

An entropically governed polymer chain (i.e. in so called theta conditions) follows a random walk in three dimensions.

is strongly dependent of polymer stiffness and can vary over orders of magnitude.

One reason that the radius of gyration is an interesting property is that it can be determined experimentally with static light scattering as well as with small angle neutron- and x-ray scattering.

This allows theoretical polymer physicists to check their models against reality.

The hydrodynamic radius is numerically similar, and can be measured with Dynamic Light Scattering (DLS).

The last transformation uses the relationship In data analysis, the radius of gyration is used to calculate many different statistics including the spread of geographical locations.

These locations have recently been collected from social media users to investigate the typical mentions of a user.

This can be useful for understanding how a certain group of users on social media use the platform.