Greenhouse Effect (HL IB Physics)

During a freak weather event, the average intensity of light received on Earth was 5 × 10⁻⁵r W m⁻². r is the radius of the Sun equal to 7 × 10⁸ m.  The average albedo was 0.8 and the average emissivity was . The light coming from the Sun to the Earth travels through a total area of 1 × 10¹⁷ m². 

Assume that σ = 6 × 10⁻⁸ W m⁻² K⁻⁴ 

What was the average temperature of the Earth during the event? 

The diagram shows a simplified model of the energy balance of the Earth's surface.

The atmosphere and the surface of the Earth can be modelled as two black body radiators each at constant temperature. The surface of the Earth receives both solar radiation and radiation emitted from the atmosphere.

The average equilibrium temperature of the Earth's surface is T_S and the average equilibrium temperature of the atmosphere is T_A = 252 K.

What is the value of T_S?

The average temperature of the surface of the Earth is 290 K, while the average surface temperature of the Moon varies from 145 K to 435 K, depending on the side that is illuminated by the Sun.

The emissivities of the surfaces of the Earth and the Moon are about the same. The radius of the Moon is approximately 4 times smaller than the radius of the Earth.

The average intensity radiated by the Earth is . What are the maximum and minimum values of the intensity radiated by the Moon?

	maximum intensity of Moon	minimum intensity of Moon
A.
B.
C.
D.

The atmosphere of Venus can be modelled in a similar way to the Earth.

The Earth's orbital radius around the Sun is 1.5 times greater than that of Venus. The solar constant for the Earth is 1360 W m⁻².

In a simple climate model for Venus, the following data is used:

• Average equilibrium temperature of Venus’s atmosphere = 250 K
• Emissivity of Venus's atmosphere, e = 0.85
• Albedo of Venus's atmosphere, a = 0.75

The observed mean surface temperature  of the planet Venus is about 750 K, which is much higher than the average equilibrium temperature  of Venus's surface as predicted by the simple model.

To account for the temperature difference, the model can be modified by introducing 'layers of atmosphere'. As radiation passes through each layer, the temperature of the atmosphere steadily increases. This temperature difference is represented by the equation

Where N is the number of atmospheric layers, and each layer can be assumed to absorb and emit all of the long-wave radiation it receives.

How many atmospheric layers are needed to account for the difference between the observed and predicted temperatures?

The solar constant is quoted as an average rather than an absolute value. Which statements correctly explain this? 

1. The Earth follows an elliptical orbit around the Sun
2. The Earth rotates on an axis which is tilted at 23.5^o to the plane of its orbit
3. The energy output of the Sun varies according to an 11-year cycle

Certain gases, for example carbon dioxide and methane, are categorised as greenhouse gases because they:

Some of the energy incident on the surface of the Earth is emitted as infrared radiation. Why does this cause a ‘greenhouse effect’?

Which two assumptions are made when calculating the solar constant?

Which diagram shows the absorption spectra for ozone?