Evaluate $\lim \limits_{x \to -1^+} (x+1)^{\frac{1}{x+1}}$
You correctly reduce to evaluating $$ \lim_{x\to -1^+}\frac{\ln(x+1)}{x+1} $$ You cannot apply l'Hôpital here, because the hypotheses are not satisfied. This limit is $-\infty$, because the numerator has limit $-\infty$ and the denominator has limit $0$, but taking positive values.
So your limit is $e^{-\infty}=0$.
You should have realized that something went wrong: for $-1<x<0$, you have $$ \ln(x+1)<0,\qquad x+1>0 $$ so the limit above can't be $\infty$, because the function only takes on negative values in a right neighborhood of $-1$.
In
$$\lim \limits_{x \to -1^+} \frac{\ln(x+1)}{x+1}$$
the numerator tends to $-\infty$ and the denominator to $0^+$, so you are not in the conditions of applicability of L'Hospital.
(But that limit is $-\infty$ and the initial one is $0$.)
Note that the limit can be evaluated directly, as should be always done as first attempt, indeed
$$x+1 \to 0^+\implies \frac1{x+1}\to \infty$$
and $0^\infty$ is not an indeterminate form therefore
$$\lim \limits_{x \to -1^+} (x+1)^{\frac{1}{x+1}}=0^\infty=0$$
As an alternative, to avoid confusion, let $y=x+1$ with $y\to 0^+$ and conclude in the same way.