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自由粒子

在物理學裏，自由粒子是不被位勢束縛的粒子。在經典力學裏，一個自由粒子所感受到外來的淨力是0。

假若，一個粒子的能量大於在任何地點 $x\,\!$ 的位勢， $E>V(x)\,\!$ ，不會被位勢束縛，則稱此粒子為自由粒子。更強版的定義，還要求位勢為常數 $V(x)=V_{0}\,\!$ 。假若，一維空間分為幾個區域，只有在每個區域內，位勢為常數；在區域與區域之間，位勢不相等，則稱此粒子為半自由粒子。自由粒子或半自由粒子的能量大於位勢， $E>V(x)\,\!$ ，不會被位勢束縛，能量不是離散能量譜的特殊值，而是大於或等於 $V_{0}\,\!$ 的任意值。

本條目只論述強版定義的自由粒子。由於能量與位勢都不是絕對值，可以設定位勢為0，再根據新舊位勢的差額，調整能量。

古典自由粒子

古典自由粒子的特點是它移動的速度 $\mathbf {v} \,\!$ 是不變的。它的動量 $\mathbf {p} \,\!$ 是

\mathbf {p} =m\mathbf {v} \,\!

。

其中， $m\,\!$ 是粒子的質量。

能量 $E\,\!$ 是

E={\frac {1}{2))mv^{2}\,\!

。

非相對論性的自由粒子

描述一個非相對論性自由粒子的含時薛丁格方程式為

-{\frac {\hbar ^{2)){2m))\nabla ^{2}\ \Psi (\mathbf {r} ,t)=i\hbar {\frac {\partial }{\partial t))\Psi (\mathbf {r} ,t)

；

其中， $\hbar$ 是約化普朗克常數， $\Psi (\mathbf {r} ,t)$ 是粒子的波函數， $\mathbf {r}$ 是粒子的位置， $t$ 是時間。

這薛丁格方程式有一個平面波解：

{\displaystyle \Psi (\mathbf {r} ,t)=e^{i(\mathbf {k} \cdot \mathbf {r} -\omega t)))

；

其中， $\mathbf {k}$ 是波向量， $\omega$ 是角頻率。

將這公式代入薛丁格方程，這兩個變數必須遵守關係式

{\frac {\hbar ^{2}k^{2)){2m))=\hbar \omega \,\!

。

由於粒子存在的機率等於1，波函數 $\Psi (\mathbf {r} ,t)\,\!$ 必須歸一化，才能夠表達出正確物理意義。對於一般的自由粒子而言，這不是問題。因為，自由粒子的波函數，在位置或動量方面，都是局部性的。

動量的期望值是

\langle \mathbf {p} \rangle =\langle \Psi |-i\hbar \nabla |\Psi \rangle =\hbar \mathbf {k} \,\!

。

能量的期望值是

\langle E\rangle =\langle \Psi |i\hbar {\frac {\partial }{\partial t))|\Psi \rangle =\hbar \omega \,\!

。

代入波向量 $\mathbf {k} \,\!$ 與角頻率 $\omega \,\!$ 的關係方程，可以得到熟悉的能量與動量的關係方程：

\langle E\rangle ={\frac {\langle p\rangle ^{2)){2m))\,\!

。

波的群速度 $v_{g}\,\!$ 定義為

v_{g}={\frac {\mathrm {d} \omega }{\mathrm {d} k))={\frac {\mathrm {d} E}{\mathrm {d} p))=v\,\!

；

其中， $v\,\!$ 是粒子的經典速度。

波的相速度 $v_{p}\,\!$ 定義為

v_{p}={\frac {\omega }{k))={\frac {E}{p))={\frac {p}{2m))={\frac {v}{2))\,\!

。

在量子力學裏，一個自由粒子的動量與能量不必須擁有特定的值。自由粒子的波函數以波包函數表示為

\Psi (\mathbf {r} ,t)={\frac {1}{(2\pi )^{3/2))}\int _{\mathbb {K} }A(\mathbf {k} )e^{i(\mathbf {k} \cdot \mathbf {r} -\omega t)}\mathrm {d} \mathbf {k} \,\!

；

其中，積分區域 $\mathbb {K}$ 是 $\mathbf {k}$ -空間。

為了方便計算，只考虑一維空間，

\Psi (x,t)={\frac {1}{\sqrt {2\pi ))}\int _{-\infty }^{\infty }A(k)~e^{i(kx-\omega (k)t)}\ \mathrm {d} k\,\!

；

其中，振幅 $A(k)\,\!$ 是量子疊加的係數函數。

逆反過來，係數函數表示為

A(k)={\frac {1}{\sqrt {2\pi ))}\int _{-\infty }^{\,\infty }\Psi (x,\ 0)~e^{-ikx}\,\mathrm {d} x\,\!

；

其中， $\Psi (x,\ 0)\,\!$ 是在時間 $t=0\,\!$ 的波函數。

所以，知道在時間 $t=0\,\!$ 的波函數 $\Psi (x,\ 0)\,\!$ ，通過傅立葉轉換，可以推導出在任何時間的波函數 $\Psi (x,t)\,\!$ 。

相對論性的自由粒子

相對論性的自由粒子的量子行為，需要用特別的方程專門描述：

克莱因-戈尔登方程描述中性的，自旋為零的，相對論性的自由粒子的量子行為。
狄拉克方程描述相對論性的電子（自旋為 $1/2\,\!$ ）的量子行為。

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