2 ² J z=0x= -√4-2² 4-x²-2 y=0 N dydxdz

Convert the following triple integral to cylindrical coordinates or spherical coordinates (do NOT evaluate):

Transcribed Image Text:

This image shows a triple integral used in multivariable calculus, possibly to find the volume under a certain surface. The integral is presented as follows: \[ \int_{z=0}^{2} \int_{x=-\sqrt{4-z^2}}^{\sqrt{4-z^2}} \int_{y=0}^{\sqrt{4-x^2-z^2}} z \, dy \, dx \, dz = \] Here’s a breakdown of the integral: 1. **The First Integral \( \int_{z=0}^{2} \)**: - The outermost integral is with respect to \( z \) and it spans from 0 to 2. 2. **The Second Integral \( \int_{x=-\sqrt{4-z^2}}^{\sqrt{4-z^2}} \)**: - The range of \( x \) depends on \( z \) and goes from \( -\sqrt{4-z^2} \) to \( \sqrt{4-z^2} \). 3. **The Third Integral \( \int_{y=0}^{\sqrt{4-x^2-z^2}} \)**: - The range of \( y \) also depends on \( x \) and \( z \), going from 0 to \( \sqrt{4-x^2-z^2} \). 4. **The Integrand**: - The integrand is \( z \), which is the function being integrated with respect to \( y \), \( x \), and \( z \). This integral describes the volume enclosed by a certain surface or solid in a three-dimensional space, where the bounds for each variable depend on the others, suggesting a specific region of space being considered.