Continuous version of binomial expansion
The binomial power series is defined for any exponent $\alpha\in\mathbb{R}$ by $$(1+x)^{\alpha}=\sum_{k=0}^{\infty}\dfrac{\alpha(\alpha-1)\cdots(\alpha-k+1)}{k!}x^k$$ The fraction generalizes binomial coefficients. If $\alpha$ is a non-negative integer the series is actually finite since eventually $\alpha=k$ for some value of $k$ and gives the usual binomial expansion. Otherwise it is infinite.
As this is a series one needs to worry about convergence. The main results are that the series is always convergent when $|x|<1$, always divergent when $|x|>1$ except when $\alpha\in\mathbb{N}$ (since the series is finite then). When $|x|= 1$ the behaviour of the series depends more subtly on $\alpha$ (this case is mostly relevant when we allow $x$ to be complex).
A slight modification along the lines of $$(a+b)^x=a^x\left(1+\dfrac{b}{a}\right)^x$$ lets you handle the more general version that you have in mind.
You can find a derivation on the wiki page https://en.wikipedia.org/wiki/Binomial_series or in any text about power series, as the binomial series is a very standard and useful power series.
NB: Both $\alpha$ and $x$ can actually be complex in this discussion without much changes.