The temperature of furance is `2000^(@)C`, in its spectrum the maximum intensity is obtained at about `4000Å`. If the maximum intensity is at `2000Å`,calculate the temperature of the furnace is .^(@)C`.

The temperature of a furnace is 827^@C . At which wavelength will it radiate maximum energy?

The temperature of a furnace is 2327^(@)C and the intensity is maximum in its radiation spectrum at 12000Å. If the intensity in the spectrum of a star is maximum at 4800Å, then the surface temperature of the star is

The temperature of a furnace is 2324^(@)C and the intensity is maximum in its radiation spectrum nearly at 12,000Å .If the intensity in the spectrum of star is maximum nearly at 4800Å , then the surface temperature of star is nearly:

The temperature of a furnace is 2227^(@)C and the intensity is maximum in its spectrum nearly at 12000 A^(@) If the intensity in the spectrum of star is maximum nearly at 48000 A^(@) then the surface temperature of the star is .

The maximum wavelength observed in the spectral energy distribution of sun is at 4673 Å, at a temperature of about 6000 K. For a star, this maximum is at 9000 Å. Calculate the temperature of the star.

A heated body emits radiation which has maximum intensity at frequency v_m If the temperature of the body is doubled:

A black body at 1500K emits maximum energy of wavlength 20000 Å . If sun emits maximum energy of wavelength 5500Å , what would be the temperature of sun.

The maximum energy in thermal radiation from a source occurs at the wavelength 4000Å. The effective temperature of the source i

The temperature of sun is 5500 K and it emits maximum intensity radiation in the yellow region (5.5 xx10^(-7)m) . The maximum radiation from a furnace occurs at wavelength 11 xx 10^(-7)m The temperature of furnace is

When the temperature of black body rises, then the wavelength corresponding to the maximum intensity (lamda_(m))