PREVIOUS ANSWERS ASK YOUR TEACHER PRACTICE ANOTHER If the infinite curve $$ y=e^{-7 x}, x \geq 0 $$, is rotated about the $$ x $$-axis, find the area of the resulting surface. Need Help? Read It

Question

UpStudy AI · Accepted Answer

We first recall that the formula for the surface area generated by revolving a curve $$ y=f(x) $$ about the $$ x $$-axis, from $$ x=a $$ to $$ x=b $$, is
$$
S = 2\pi \int_{a}^{b} f(x) \sqrt{1+\left(f'(x)\right)^2}\, dx.
$$
Since the curve is given by
$$
y = e^{-7x} \quad \text{for } x \ge 0,
$$
we have
$$
f(x) = e^{-7x} \quad \text{and} \quad f'(x) = \frac{d}{dx}\left(e^{-7x}\right) = -7e^{-7x}.
$$

Thus,
$$
1+\left(f'(x)\right)^2 = 1+ \left(-7e^{-7x}\right)^2 = 1+ 49e^{-14x}.
$$

The surface area is then
$$
S = 2\pi \int_{0}^{\infty} e^{-7x} \sqrt{1+49e^{-14x}}\, dx.
$$

### Change of Variables

Let
$$
u = e^{-7x}\quad \Longrightarrow \quad \frac{du}{dx} = -7e^{-7x} = -7u.
$$
Thus,
$$
dx = -\frac{1}{7u}\, du.
$$
The limits change as follows:
- When $$ x=0 $$, $$ u = e^{0} = 1 $$.
- When $$ x\to \infty $$, $$ u = e^{-7\cdot\infty} = 0 $$.

Substitute into the integral:
$$
S = 2\pi \int_{u=1}^{0} u \sqrt{1+49u^2} \left(-\frac{1}{7u}\, du\right).
$$
Notice that the factor $$ u $$ in the numerator cancels with the $$ u $$ in the denominator:
$$
S = \frac{2\pi}{7} \int_{1}^{0} \sqrt{1+49u^2}\, (-du).
$$
Reversing the limits (which removes the negative sign) gives:
$$
S = \frac{2\pi}{7} \int_{0}^{1} \sqrt{1+49u^2}\, du.
$$

### Evaluating the Integral

We now need to evaluate the integral
$$
I = \int_{0}^{1} \sqrt{1+49u^2}\, du.
$$
A standard formula is:
$$
\int \sqrt{1+a^2x^2}\, dx = \frac{x}{2}\sqrt{1+a^2x^2} + \frac{\operatorname{arcsinh}(ax)}{2a} + C.
$$
Here, $$ a=7 $$. Therefore,
$$
\int \sqrt{1+49u^2}\, du = \frac{u}{2}\sqrt{1+49u^2} + \frac{\operatorname{arcsinh}(7u)}{14}+C.
$$

Evaluating from $$ u=0 $$ to $$ u=1 $$:
$$
I = \left[\frac{u}{2}\sqrt{1+49u^2} + \frac{\operatorname{arcsinh}(7u)}{14}\right]_{0}^{1}
= \frac{1}{2}\sqrt{1+49} + \frac{\operatorname{arcsinh}(7)}{14} - \left(0 + 0\right).
$$
Since $$ \sqrt{1+49} = \sqrt{50}=5\sqrt{2} $$, we have
$$
I = \frac{5\sqrt{2}}{2} + \frac{\operatorname{arcsinh}(7)}{14}.
$$

### Final Expression for the Surface Area

Substitute $$ I $$ back into the expression for $$ S $$:
$$
S = \frac{2\pi}{7} \left(\frac{5\sqrt{2}}{2} + \frac{\operatorname{arcsinh}(7)}{14}\right).
$$
To combine the two terms, find a common denominator inside the parentheses:
$$
\frac{5\sqrt{2}}{2} = \frac{35\sqrt{2}}{14},
$$
so
$$
S = \frac{2\pi}{7} \left(\frac{35\sqrt{2}+ \operatorname{arcsinh}(7)}{14}\right)
= \frac{2\pi \left(35\sqrt{2}+ \operatorname{arcsinh}(7)\right)}{98}.
$$
Simplify by dividing numerator and denominator by 2:
$$
S = \frac{\pi \left(35\sqrt{2}+ \operatorname{arcsinh}(7)\right)}{49}.
$$

Thus, the area of the surface generated by rotating the curve $$ y=e^{-7x} $$ about the $$ x $$-axis is
$$
\boxed{S = \frac{\pi \left(35\sqrt{2}+ \operatorname{arcsinh}(7)\right)}{49}}.
$$
The area of the surface generated by rotating the curve $$ y=e^{-7x} $$ about the $$ x $$-axis is $$ \frac{\pi \left(35\sqrt{2}+ \operatorname{arcsinh}(7)\right)}{49} $$.

PREVIOUS ANSWERS ASK YOUR TEACHER PRACTICE ANOTHER If the infinite curve \( y=e^{-7 x}, x \geq 0 \), is rotated about the \( x \)-axis, find the area of the resulting surface. Need Help? Read It

Upstudy AI Solution

Answer

Solution

Bonus Knowledge

Related Questions

Latest Calculus Questions