If $\int_{1}^{2}e^{x^2}~dx=\alpha$ ,then show that $\int_{e}^{e^4}\sqrt{\ln x}~dx=2e^4-e-\alpha$
How I proceed:$\int_{e}^{e^4}\sqrt{\ln x}~dx=2\int_{1}^{2}z^2e^{z^2}~dx$ Then I can't proceed. Please help.
If $\int_{1}^{2}e^{x^2}~dx=\alpha$ ,then show that $\int_{e}^{e^4}\sqrt{\ln x}~dx=2e^4-e-\alpha$
How I proceed:$\int_{e}^{e^4}\sqrt{\ln x}~dx=2\int_{1}^{2}z^2e^{z^2}~dx$ Then I can't proceed. Please help.
Integrating by parts we get $ \int _1 ^2 z \cdot 2z e^{z^2} \, dz = \Big [ze^{z^2} \Big ]_1 ^2 - \int _1 ^2 e^{z^2}\, dz. $
You can also see it pictorially. In the figure below, the curve between the red and blue areas is $y=e^{x^2}$, so the blue area is $\alpha$, and the desired integral is the red area. The area of the large rectangle is clearly $2e^4$, and the area of the black rectangle is $e$, so $\int_{e}^{e^4}\sqrt{\ln x}~dx=\text{red area}=2e^4-e-\text{blue area}=2e^4-e-\alpha\;$