149538 The spectral energy distribution of a star is maximum at twice temperature as that of sun. The total energy radiated by star is

149539 What will be the ratio of temperatures of sun and moon if the wavelengths of their maximum emission radiations rates are $140 \AA$ and $4200 \AA$ respectively?

149540 Solar radiation emitted by sun correspond to that emitted by black body at a temperature of $6000 \mathrm{~K}$. Maximum intensity is emitted at wavelength of $4800 \AA$. If the sun was to cool down from $6000 \mathrm{~K}$ to $3000 \mathrm{~K}$, then the peak intensity of emitted radiation would occur at a wavelength

149541 The wavelength $\lambda_{\mathrm{m}}$ of maximum intensity of emission of solar radiation is $\lambda_{\mathrm{m}}=4753 \AA$ and from moon is $14 \mu \mathrm{m}$. The surface temperature of sun and moon are
(Given b $=\mathbf{2 . 8 9 8} \times \mathbf{1 0}^{-3}$ meter Kelvin)

149538 The spectral energy distribution of a star is maximum at twice temperature as that of sun. The total energy radiated by star is

149539 What will be the ratio of temperatures of sun and moon if the wavelengths of their maximum emission radiations rates are $140 \AA$ and $4200 \AA$ respectively?

149540 Solar radiation emitted by sun correspond to that emitted by black body at a temperature of $6000 \mathrm{~K}$. Maximum intensity is emitted at wavelength of $4800 \AA$. If the sun was to cool down from $6000 \mathrm{~K}$ to $3000 \mathrm{~K}$, then the peak intensity of emitted radiation would occur at a wavelength

149541 The wavelength $\lambda_{\mathrm{m}}$ of maximum intensity of emission of solar radiation is $\lambda_{\mathrm{m}}=4753 \AA$ and from moon is $14 \mu \mathrm{m}$. The surface temperature of sun and moon are
(Given b $=\mathbf{2 . 8 9 8} \times \mathbf{1 0}^{-3}$ meter Kelvin)

149538 The spectral energy distribution of a star is maximum at twice temperature as that of sun. The total energy radiated by star is

149539 What will be the ratio of temperatures of sun and moon if the wavelengths of their maximum emission radiations rates are $140 \AA$ and $4200 \AA$ respectively?

149540 Solar radiation emitted by sun correspond to that emitted by black body at a temperature of $6000 \mathrm{~K}$. Maximum intensity is emitted at wavelength of $4800 \AA$. If the sun was to cool down from $6000 \mathrm{~K}$ to $3000 \mathrm{~K}$, then the peak intensity of emitted radiation would occur at a wavelength

149541 The wavelength $\lambda_{\mathrm{m}}$ of maximum intensity of emission of solar radiation is $\lambda_{\mathrm{m}}=4753 \AA$ and from moon is $14 \mu \mathrm{m}$. The surface temperature of sun and moon are
(Given b $=\mathbf{2 . 8 9 8} \times \mathbf{1 0}^{-3}$ meter Kelvin)

149538 The spectral energy distribution of a star is maximum at twice temperature as that of sun. The total energy radiated by star is

149539 What will be the ratio of temperatures of sun and moon if the wavelengths of their maximum emission radiations rates are $140 \AA$ and $4200 \AA$ respectively?

149540 Solar radiation emitted by sun correspond to that emitted by black body at a temperature of $6000 \mathrm{~K}$. Maximum intensity is emitted at wavelength of $4800 \AA$. If the sun was to cool down from $6000 \mathrm{~K}$ to $3000 \mathrm{~K}$, then the peak intensity of emitted radiation would occur at a wavelength

149541 The wavelength $\lambda_{\mathrm{m}}$ of maximum intensity of emission of solar radiation is $\lambda_{\mathrm{m}}=4753 \AA$ and from moon is $14 \mu \mathrm{m}$. The surface temperature of sun and moon are
(Given b $=\mathbf{2 . 8 9 8} \times \mathbf{1 0}^{-3}$ meter Kelvin)