(a) If Kepler 1606b has no atmosphere and an albedo similar to the Earth's (albedo of...

Kepler 1606b is an exoplanet: a planet orbiting a star different than our own. Named for...

Kepler 1606b is an exoplanet: a planet orbiting a star different than our own. Named for the star it orbits (Kepler 1606, a star about 3000 light-years away), it was discovered in the year 2016 by the Kepler space telescope. Kepler 1606b orbits its star a little bit closer than the Earth's orbit to the Sun, at a distance of 0.64⋅?????ℎ, where ?????ℎ=1.50×1011 m is the radius of Earth's orbit. The star Kepler 1606 is bit cooler than our Sun,...

Kepler 1606b is an exoplanet: a planet orbiting a star different than our own. Named for...

Kepler 1606b is an exoplanet: a planet orbiting a star different than our own. Named for the star it orbits (Kepler 1606, a star about 3000 light-years away), it was discovered in the year 2016 by the Kepler space telescope. Kepler 1606b orbits its star a little bit closer than the Earth's orbit to the Sun, at a distance of 0.64⋅rearth, where rearth=1.50×1011 m is the radius of Earth's orbit. The star Kepler 1606 is bit cooler than our Sun,...

You are embedded in the Kepler program in which planetary systems are being detected around other...

You are embedded in the Kepler program in which planetary systems are being detected around other stars. You detect a possible planet in orbit around a star whose peak wavelength of radiation is 0.38 microns, which is considerably shorter than that of our Sun. Calculate the “goldilocks distance” for this system, the orbital distance from this star at which you would expect a planet to have a surface temperature of 0°C. (Assume the planet has an albedo of 0.3, and...

(a) Calculate the equilibrium temperature of the present-day Earth, assuming the albedo is 0.3 for incoming...

(a) Calculate the equilibrium temperature of the present-day Earth, assuming the albedo is 0.3 for incoming solar radiation but that the emissivity is 1.0 out in the infrared where Earth emits. (b) Compare your answer to (a) to the freezing point of water. Should the Earth be completely frozen over now? Why or why not? (c) Now assume the Earth's actual average temperature today is 290 K and the difference between 290 K and the present equilibrium temperature would be...

Calculate Ts for the given values of the solar input. The discussion part of each question...

Calculate Ts for the given values of the solar input. The discussion part of each question emphasizes physical understanding by comparing Earth to this simple planet. Constant albedo A; use A=0.12. The value of s=5.67 X 10-8 Wm-2K-4. (a) An Earth without atmosphere: There would be no clouds and no aerosols for simplity, the Earth’s surface albedo is 0.12. i) Calculate Ts for Sß = 342 W/m2, the global average input and A=0.12. Compare to the global average Ts on...

The Earth's surface temperature is about 15∘C, far above the average temperature of the atmosphere of...

The Earth's surface temperature is about 15∘C, far above the average temperature of the atmosphere of −33∘C, mainly because: a)The visible light from the Sun is almost completely absorbed by the atmosphere and radiated back to the Earth’s surface but in a form of infrared radiation. b)The infrared radiation from the Sun is almost completely absorbed by the atmosphere and radiated to the Earth. c)The infrared radiation from the Earth’s surface is almost completely absorbed by the atmosphere and a...

Approximating Earth's atmosphere as a layer of gas 7.3 km thick, with uniform density 1.2 kg/m3...

Approximating Earth's atmosphere as a layer of gas 7.3 km thick, with uniform density 1.2 kg/m3 , calculate the total mass of the atmosphere. Compare your result with Earth's mass. Express your answer using two significant figures. Compare your result with Earth's mass. Express your answer using two significant figures.

A star with a radius four times that of our Sun is observed to have a...

A star with a radius four times that of our Sun is observed to have a rough blackbody spectrum that peaks around 400nm. The star illuminates a planet with the mass of the Earth at a distance of 0.7AU. This planet has a radius twice that of the Earth and absorbs a power of 2.82*1019 W. a) What is the planet’s albedo? The constant in Wien’s law is 2.9*10-3 m x K b) Assuming the equilibrium temperature is approximately that...

If the Earth's atmosphere were to be slowly removed, then what would happen to a marshmallow?...

If the Earth's atmosphere were to be slowly removed, then what would happen to a marshmallow? 1)It would become smaller in size. 2)It would become more dense. 3)Nothing would happen to it. 4)It would become a hollow cylinder in its shape. 5)It would become larger in size.

The intensity of sunlight striking Earth's upper atmosphere (called the solar constant) is 1.35 kW/m2. (a)...

The intensity of sunlight striking Earth's upper atmosphere (called the solar constant) is 1.35 kW/m2. (a) Find Erms and Brms due to the sun at the upper atmosphere of Earth. Erms =  V/m Brms =  µT (b) Find the average power output of the sun. W (c) Find the intensity at the surface of the sun. W/m2 (d) Find the radiation pressure at the surface of the sun. Pa