Answer to Question #201542 in Astronomy | Astrophysics for J17

Let us determine the angular size of the spot. We should divide the diameter of the spot by the distance, so we'll get the size in radians:

"\\alpha = \\dfrac{R}{d} = \\dfrac{16500\\,\\mathrm{km}}{968\\cdot10^6\\,\\mathrm{km}} \\approx 1.7\\cdot10^{-5}\\,\\mathrm{rad}."

(a) The diameter of the lens will be smallest, if this angle is equal to the angular resolution of the telescope, or

"\\alpha = 1.22\\dfrac{\\lambda}{D}" . Therefore

"1.22\\dfrac{\\lambda}{D} = 1.7\\cdot10^{-5},\\;\\; D= \\dfrac{1.22\\lambda}{1.7\\cdot10^{-5}}, \\\\\nD = \\dfrac{1.22\\cdot600\\cdot10^{-9}\\,\\mathrm{m}}{1.7\\cdot10^{-5}} = 0.04\\,\\mathrm{m}."

(b) The smallest angular size of the crater should not be less than the angular resolution of the telescope. So let us consider an equality

"\\alpha = 1.22\\dfrac{\\lambda}{D} = 1.7\\cdot10^{-5} = \\dfrac{d_c}{L}," where "d_c" is the diameter of the crater and "L" is the distance from Earth to Moon.

Therefore, "d_c = 1.7\\cdot10^{-5}\\cdot L = 1.7\\cdot10^{-5}\\cdot 384400\\,\\mathrm{km}. = 6.6\\,\\mathrm{km}."