An EM wave of intensity I falls on a surface kept in vacuum and exerts radiation pressure p on it. Which of the following are true ?

An EM wave of intensity I falls on a surface kept in vacuum and exerts

1.	An EM wave of intensity I falls on a surface kept in vacuum and exerts radiation pressure p on it. Which of the following are true ?
Answer» Radiation pressure is `(I)/(c )` if the wave is totally absorbed. Radiation pressure is `(I)/(c )` if the wave is totally reflected. Radiation pressure is `(2I)/(c )` if the wave is totally reflected. Radiation pressure is in the range `(I)/(c )lt p lt (2I)/(c )` for real surfaces. Solution :Radiation pressure (P) is force applied by electromagnetic wave on unit AREA that is change in momentum on unit area. Change in momentum per unit area in unit time, `P=("Intensity")/("Wave speed")=(I)/(c )` Change in momentum per unit area per unit time. `Delta p =(Delta I)/(c )` (Radiation pressure p) Change in momentum per uunit time per unit area `=(I)/(c )` When wave is completely absorbed by surface then momentum of reflected wave in unit time per unit area = 0 (ZERO) Radiation pressure, P = Change in momentum per unit area PERUNIT time `=(Delta I)/(c )=(I)/(c )-0=(I)/(c )` When wave is completely reflected then momentum of wave per unit area per unit time`=-(I)/(c )` `therefore` Radiation pressure `P=(I)/(c )-(-(I)/(c ))=(2I)/(c )` Here P is between `(I)/(c )` and `(2I)/(c )`. HENCE, option (A, C, D) are CORRECT.

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An EM wave of intensity I falls on a surface kept in vacuum and exerts radiation pressure p on it. Which of the following are true ?

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