358856 A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is \(20\,g\). Assume that there is no absorption in the lens and that \({30 \%}\) of the light emitted by the source goes through the lens. The power of the source needed to support the weight of the mirror is

358857 Light with an energy flux of \(18\;W/c{m^2}\) falls on a non- reflecting suface at normal incidence. If the surface has an area of \(20\;c{m^2}\), find the average force exerted on the suface during a 30 minute time span.

358858 Find the radiation pressure of solar radiation on the surface of earth. Solar constant is \(1.4\,kW{m^{ - 2}}\) (Assume complete absorption)

358859 Statement A :
Electromagnetic waves exert radiation pressure.
Statement B :
Electromagnetic waves carry energy.

358860 Light with an energy flux of \(20\;W/c{m^2}\) falls on a non-reflecting surface at normal incidence. If the surface has an area of \(30\;c{m^2}\), the total momentum delivered (for complete absorption) during \(30\;\min \) is

358856 A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is \(20\,g\). Assume that there is no absorption in the lens and that \({30 \%}\) of the light emitted by the source goes through the lens. The power of the source needed to support the weight of the mirror is

358857 Light with an energy flux of \(18\;W/c{m^2}\) falls on a non- reflecting suface at normal incidence. If the surface has an area of \(20\;c{m^2}\), find the average force exerted on the suface during a 30 minute time span.

358858 Find the radiation pressure of solar radiation on the surface of earth. Solar constant is \(1.4\,kW{m^{ - 2}}\) (Assume complete absorption)

358859 Statement A :
Electromagnetic waves exert radiation pressure.
Statement B :
Electromagnetic waves carry energy.

358860 Light with an energy flux of \(20\;W/c{m^2}\) falls on a non-reflecting surface at normal incidence. If the surface has an area of \(30\;c{m^2}\), the total momentum delivered (for complete absorption) during \(30\;\min \) is

358856 A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is \(20\,g\). Assume that there is no absorption in the lens and that \({30 \%}\) of the light emitted by the source goes through the lens. The power of the source needed to support the weight of the mirror is

358857 Light with an energy flux of \(18\;W/c{m^2}\) falls on a non- reflecting suface at normal incidence. If the surface has an area of \(20\;c{m^2}\), find the average force exerted on the suface during a 30 minute time span.

358858 Find the radiation pressure of solar radiation on the surface of earth. Solar constant is \(1.4\,kW{m^{ - 2}}\) (Assume complete absorption)

358859 Statement A :
Electromagnetic waves exert radiation pressure.
Statement B :
Electromagnetic waves carry energy.

358860 Light with an energy flux of \(20\;W/c{m^2}\) falls on a non-reflecting surface at normal incidence. If the surface has an area of \(30\;c{m^2}\), the total momentum delivered (for complete absorption) during \(30\;\min \) is

358856 A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is \(20\,g\). Assume that there is no absorption in the lens and that \({30 \%}\) of the light emitted by the source goes through the lens. The power of the source needed to support the weight of the mirror is

358857 Light with an energy flux of \(18\;W/c{m^2}\) falls on a non- reflecting suface at normal incidence. If the surface has an area of \(20\;c{m^2}\), find the average force exerted on the suface during a 30 minute time span.

358858 Find the radiation pressure of solar radiation on the surface of earth. Solar constant is \(1.4\,kW{m^{ - 2}}\) (Assume complete absorption)

358859 Statement A :
Electromagnetic waves exert radiation pressure.
Statement B :
Electromagnetic waves carry energy.

358860 Light with an energy flux of \(20\;W/c{m^2}\) falls on a non-reflecting surface at normal incidence. If the surface has an area of \(30\;c{m^2}\), the total momentum delivered (for complete absorption) during \(30\;\min \) is

358856 A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is \(20\,g\). Assume that there is no absorption in the lens and that \({30 \%}\) of the light emitted by the source goes through the lens. The power of the source needed to support the weight of the mirror is

358857 Light with an energy flux of \(18\;W/c{m^2}\) falls on a non- reflecting suface at normal incidence. If the surface has an area of \(20\;c{m^2}\), find the average force exerted on the suface during a 30 minute time span.

358858 Find the radiation pressure of solar radiation on the surface of earth. Solar constant is \(1.4\,kW{m^{ - 2}}\) (Assume complete absorption)

358859 Statement A :
Electromagnetic waves exert radiation pressure.
Statement B :
Electromagnetic waves carry energy.

358860 Light with an energy flux of \(20\;W/c{m^2}\) falls on a non-reflecting surface at normal incidence. If the surface has an area of \(30\;c{m^2}\), the total momentum delivered (for complete absorption) during \(30\;\min \) is