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According to the principles of special relativity, the momentum of an object depends on its velocity. The momentum of an object is given by the equation:

p = m * v / sqrt(1 - v^2/c^2)

Where: p is the momentum of the object, m is its mass, v is its velocity, c is the speed of light in a vacuum.

In this case, let's assume the initial velocity of the particle is v_initial. If the velocity of the particle is doubled, the new velocity becomes 2 * v_initial.

To determine what happens to the momentum, we can compare the initial and final momenta.

Initial momentum: p_initial = m * v_initial / sqrt(1 - v_initial^2/c^2)

Final momentum: p_final = m * (2 * v_initial) / sqrt(1 - (2 * v_initial)^2/c^2)

Simplifying the expression:

p_final = 2 * m * v_initial / sqrt(1 - 4 * v_initial^2/c^2)

From the equations, it is evident that doubling the velocity results in the doubling of the particle's momentum.

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