Evaluate the double integral ∬R(3x−y)dA, where R is the region in the first quadrant enclosed by the circle x^2+y^2=4 and the lines x=0 and y=x, by changing to polar coordinates.

To evaluate the double integral using polar coordinates, we need to express the differential area element d𝑨 in terms of polar coordinates. The conversion formulas are:

𝑥 = 𝑟cos𝜃
𝑦 = 𝑟sin𝜃
d𝑨 = 𝑟d𝑟d𝜃

The region R in the first quadrant enclosed by the circle x^2 + y^2 = 4, x = 0, and y = x can be expressed in polar coordinates as follows:

𝑧: 𝜃 ∈ [0, π/4]
𝑟: 𝑟 ∈ [0, 2]

Now, let's substitute the expressions for 𝑥, 𝑦, and d𝑨 into the integral:

∬𝑅 (3𝑥 − 𝑦) d𝐴 = ∫[𝜃=0 to 𝜃=π/4] ∫[𝑟=0 to 𝑟=2] (3(𝑟cos𝜃) − (𝑟sin𝜃)) 𝑟 d𝑟 d𝜃

Expanding and simplifying the expression inside the integral:

∫[𝜃=0 to 𝜃=π/4] ∫[𝑟=0 to 𝑟=2] (3𝑟cos𝜃 − 𝑟sin𝜃) 𝑟 d𝑟 d𝜃
= ∫[𝜃=0 to 𝜃=π/4] ∫[𝑟=0 to 𝑟=2] (3𝑟^2cos𝜃 − 𝑟^2sin𝜃) d𝑟 d𝜃

Now, we evaluate the inner integral by integrating with respect to r:

∫[𝑟=0 to 𝑟=2] (3𝑟^2cos𝜃 − 𝑟^2sin𝜃) d𝑟
= (𝑟^3cos𝜃/3 − 𝑟^3sin𝜃/3) evaluated from 𝑟=0 to 𝑟=2
= (8cos𝜃/3 − 8sin𝜃/3) - (0) = 8cos𝜃/3 - 8sin𝜃/3

Now, we evaluate the outer integral by integrating with respect to 𝜃:

∫[𝜃=0 to 𝜃=π/4] (8cos𝜃/3 - 8sin𝜃/3) d𝜃
= (8sin𝜃/3 + 8cos𝜃/3) evaluated from 𝜃=0 to 𝜃=π/4
= (8(sin(π/4))/3 + 8(cos(π/4))/3) - (8(0)/3)
= (8/√2)/3 + (8/√2)/3
= (8√2 + 8√2)/3
= 16√2/3

Therefore, the value of the double integral is 16√2/3.