It does not lead to an infinite loop: the exponent on z was reduced by 1, and if you repeat the process two more times, it will disappear, leaving you with a simple exponential to integrate. ...

\displaystyle=-{e}^{{-{t}}}{\left({t}+{1}\right)}+{C} Explanation: For \displaystyle{u},{v} functions of \displaystyle{t} , \displaystyle\int{u}{v}'{\left.{d}{t}\right.}={u}{v}-\int{u}'{v}{\left.{d}{t}\right.} ...

Well done. But you do not need me to check it. You can check it for yourself by differentiating. This is the case for any indefinite integral.

if \color{green}{u} = \color{magenta}{x^3} and du = 3x^2 dx, then \color{red}{\frac{1}{3}du} = \color{blue}{x^2 dx}, so \int x^2 e^{x^3}\;dx = \int e^{\color{magenta}{x^3}}\color{blue}{x^2 dx} = \int e^{\color{green}{u}}\color{red}{\frac{1}{3}du} ...

No, why should it? The integral which by substitution is equivalent to the first is -\int e^{u}\mathrm du=-e^{u}+C Now what is u? It's -x, so substitute back in for the variable you actually ...

Or you can note that, since e^t is a effectively a constant, the variable of integration being u, we have \int e^{t - u} \,du = e^t \int e^{-u}\,du = e^t (-e^{-u}) = -e^{t - u}. \tag{1} The ...