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Particle that, in some sense, is not bound by an external force, or equivalently not in a region where its potential energy varies
In physics, a free particle is a particle that, in some sense, is not bound by an external force, or equivalently not in a region where its potential energy varies. In classical physics, this means the particle is present in a "field-free" space. In quantum mechanics, it means a region of uniform potential, usually set to zero in the region of interest since potential can be arbitrarily set to zero at any point (or surface in three dimensions) in space.
Classical free particle
The classical free particle is characterized by a fixed velocityv. The momentum is given by
where m is the mass of the particle and v is the vector velocity of the particle.
Quantum free particle
Propagation of de Broglie waves in 1d - real part of the complex amplitude is blue, imaginary part is green. The probability (shown as the colour opacity) of finding the particle at a given point x is spread out like a waveform, there is no definite position of the particle. As the amplitude increases above zero the curvature decreases, so the decreases again, and vice versa - the result is an alternating amplitude: a wave. Top: Plane wave. Bottom: Wave packet.
A free particle with mass in non-relativistic quantum mechanics is described by the free Schrödinger equation:
The eigenvalue spectrum is infinitely degenerate since for each eigenvalue E>0, there corresponds an infinite number of eigenfunctions corresponding to different directions of .
The De Broglie relations: apply. Since the potential energy is (stated to be) zero, the total energy E is equal to the kinetic energy, which has the same form as in classical physics:
As for all quantum particles free or bound, the Heisenberg uncertainty principles apply. It is clear that since the plane wave has definite momentum (definite energy), the probability of finding the particle's location is uniform and negligible all over the space. In other words, the wave function is not normalizable in a Euclidean space, these stationary can not correspond to physical realizable states. 
where * denotes complex conjugate, over all space is the probability of finding the particle in all space, which must be unity if the particle exists:
This is the normalization condition for the wave function. The wavefunction is not normalizable for a plane wave, but is for a wavepacket.
Increasing amounts of wavepacket localization, meaning the particle becomes more localized.
In the limit ? -> 0, the particle's position and momentum become known exactly.
Interpretation of wave function for one spin-0 particle in one dimension. The wavefunctions shown are continuous, finite, single-valued and normalized. The colour opacity (%) of the particles corresponds to the probability density (which can measure in %) of finding the particle at the points on the x-axis.
The free particle wave function may be represented by a superposition of momentum eigenfunctions, with coefficients given by the Fourier transform of the initial wavefunction:
where the integral is over all k-space and (to ensure that the wave packet is a solution of the free particle Schrödinger equation). Here is the value of the wave function at time 0 and is the Fourier transform of . (The Fourier transform is essentially the momentum wave function of the position wave function , but written as a function of rather than .)
The expectation value of the momentum p for the complex plane wave is
and for the general wave packet it is
The expectation value of the energy E is
Group velocity and phase velocity
Propagation of a wave packet, with the motion of a single peak shaded in purple. The peaks move at the phase velocity while the overall packet moves at the group velocity.
The phase velocity is defined to be the speed at which a plane wave solution propagates, namely
Note that is not the speed of a classical particle with momentum ; rather, it is half of the classical velocity.
Meanwhile, suppose that the initial wave function is a wave packet whose Fourier transform is concentrated near a particular wave vector . Then the group velocity of the plane wave is defined as
which agrees with the formula for the classical velocity of the particle. The group velocity is the (approximate) speed at which the whole wave packet propagates, while the phase velocity is the speed at which the individual peaks in the wave packet move. The figure illustrates this phenomenon, with the individual peaks within the wave packet propagating at half the speed of the overall packet.
Spread of the wave packet
The notion of group velocity is based on a linear approximation to the dispersion relation near a particular value of . In this approximation, the amplitude of the wave packet moves at a velocity equal to the group velocity without changing shape. This result is an approximation that fails to capture certain interesting aspects of the evolution a free quantum particle. Notably, the width of the wave packet, as measured by the uncertainty in the position, grows linearly in time for large times. This phenomenon is called the spread of the wave packet for a free particle.
Specifically, it is not difficult to compute an exact formula for the uncertainty as a function of time, where is the position operator. Working in one spatial dimension for simplicity, we have:
where is the time-zero wave function. The expression in parentheses in the second term on the right-hand side is the quantum covariance of and .
Thus, for large positive times, the uncertainty in grows linearly, with the coefficient of equal to . If the momentum of the initial wave function is highly localized, the wave packet will spread slowly and the group-velocity approximation will remain good for a long time. Intuitively, this result says that if the initial wave function has a very sharply defined momentum, then the particle has a sharply defined velocity and will (to good approximation) propagate at this velocity for a long time.