Atmospheric Environments - Long-wave Radiation

Long-wave radiation

Trees recorded in thermal infrared using a thermal scanner shown in false color

Learning Objectives

Explain the role of Long-wave radiation in the climate system.
Described how absorption and emission are linked & understand Kirchhoff’s law of thermal radiation.
Explain how we can measure Long-wave radiation.

What is ‘Long-wave’ radiation?

Objects emit radiation proportional to their temperature; adjusting for emittance as per the Stefan-Boltzmann equation for grey-bodies.

Wavelength (\(\lambda\)) > 3 \(\mu m\)
Long-wave radiation \(\approx\) thermal infrared radiation (TIR)
Exchanged between sky, surface and all surrounding objects

\[ E_g = \epsilon\sigma_b T^4 \qquad(1)\]

Review Short-wave vs. Long-wave

Peak spectral output of the Sun and Earth compared on a log scale

Peak spectral output of the Sun and Earth compared in natural units

Radiation Laws & Terminology

Planck’s Law: describes the full spectral output (spectra)
Wiens Law: gives the peak of the spectra
Stefan Boltzmann Law: gives the integral of the spectra
Beer’s Law: describes attenuation of radiation
Photosyntheically Active Radiation (PAR): \(\lambda\) 0.4-0.7 \(\mu\) m
Kirchhoff’s Law: relates emissivity to absorptivity

Short-wave vs Long-wave Imagery

Urban environment with buildings and trees recorded in the visible part of the electromagnetic spectrum.

Same location, recorded using a thermal infrared (TIR) camera. Dark colors = low TIR flux densities, light colors = high TIR flux densities.

Kirchhoff’s Law

Assuming no transmission the absorptivity of a body (\(a_\lambda\)) equals its emissivity (\(\epsilon_{\lambda}\)).

\[ a_{\lambda} = \epsilon_{\lambda} \qquad(2)\]

A good absorber is a good emitter
A poor absorber is a poor emitter
Wavelength specific relationship

Kirchhoff’s Law

Only applies if the wavelength considered is the same
- Do not mix them together
Only relevant to long-wave exchange in climatology
- Earth-Atmosphere system is not hot enough to emit short-wave radiation
\(a_{\lambda}\) and \(\epsilon_{\lambda}\) are ratios (portions of a whole)

\[ a_\lambda + \tau_\lambda + \alpha_\lambda = 1 \qquad(3)\]

Kirchhoff’s Law

The atmosphere is a selective absorber (and emitter) of long-wave radiation.

Aerosols and clouds are dominant when present
Most significant absorbing gases:
- H₂O
- CO₂
- O₃
- O₂
- N₂O
- CH₄

Atmospheric absorption and emission

Kirchhoff’s Law tells us that since atmospheric absorption is concentrated at these wavelengths so is atmospheric emission.

Equally, at wavelengths where the atmosphere is poor at absorbing it is poor at emitting.

Atmospheric absorption and emission

Net Long-wave Flux Density

The net long-wave radiation flux density (\(LW^*\)) at the surface is the difference between the input from the atmosphere above (\(LW\downarrow\)) and the output surface (\(LW\uparrow\)).

\[ LW^* = LW\downarrow - LW\uparrow \qquad(4)\]

Surface output includes both emissions from surface and reflected \(LW\downarrow\)
- Differs from \(SW*= SW\downarrow - SW\uparrow\)
- \(SW\uparrow\) is only reflected \(SW\), earth doesn’t emit \(SW\)!

Net Long-wave Flux Density

We can re-formulate the previous equation in terms of the Stefan-Boltzmann Law:

\[ LW^* = LW\downarrow - \epsilon_{LW}\sigma_b T_s^4 -(1-\epsilon_{LW})LW\downarrow \qquad(5)\]

How is this equivalent?

Stefan-Boltzman gives us emissions from a surface temperature \(T_s\) with a long-wave emissivity of \(\epsilon_{LW}\)

\((1-\epsilon_{LW})\) gives us reflectivity

Net Long-wave Flux Density (iClicker)

The equation on the previous slide works for long-wave radiation, because for an opaque object like the Earth’s Surface:

\[ \alpha_{LW} = (1-a_{LW}) = (1-\epsilon_{LW}) \]

A - True

B - False

Long-wave exchange

Test your knowledge (iClicker)

Is long-wave radiation emitted by the surface generally greater than that emitted by the atmosphere?

Hint: is the surface usually warmer than the atmosphere?

A - Yes

B - No

Clear Skies

Figure 1: Incoming and Outgoing Long-wave Radiation at Burns Bog July 21st, 2023.

\(LW\downarrow\) = NaN w m^-2

\(LW\uparrow\) = NaN w m^-2

\(LW^* = LW\downarrow - LW\uparrow\) = NaN w m^-2

Cloudy Skies (iClicker)

Figure 2: Incoming and Outgoing Long-wave Radiation at Burns Bog December 27th, 2022.

\(LW\downarrow\) = 350 w m^-2

\(LW\uparrow\) = 350 w m^-2

\(LW^*\) = ?

Which day was warmer? (iClicker)

Figure 3: A

Figure 4: B

The Greenhouse Gas Effect

Not a great analogy:
- Warming mostly due to reduction of convective heat transfer
- Much less due to \(LW\downarrow\) from the glass
In the Atmosphere convection is not constrained

The Greenhouse Gas Effect

Perhaps it would be better called the sweater effect?
- A sweater works by trapping and recycling \(LW\) emitted from your body

Yarrow wears a sweater to reduce her \(LW\) flux density and stay warm

The Greenhouse Gas Effect

The atmosphere is a selective absorber (and emitter) of long-wave radiation.

Aerosols and clouds are dominant when present
Most significant absorbing gases:
- H₂O
- CO₂
- O₃
- O₂
- N₂O
- CH₄

View factors

The view of the sky from an object (sky view factor; \(\psi_{sky}\)) is significant in quantifying Long-wave exchange at night. + The sky is usually ‘cold’ and an effective heat sink

Implications of \(\psi_{sky}\)

A stand of trees can keep livestock warm at night by reducing the animals’ \(\psi_{sky}\)

A tent reduces the \(\psi_{sky}\) to zero for the occupants!

These enclosures provide a source of longwave radiation to the young grape plants at night

Measuring \(LW\)

This is a pyrgeometer

Measuring \(LW\downarrow\) and \(LW\uparrow\)

Take home points

Long-wave radiation is emitted from Atmosphere (gases, aerosols, droplets) and surface at ambient temperatures.
Kirchhoff’s Law states that for a certain wavelength the absorptivity \(a_{\lambda\)} equals emissivity \(\epsilon_{\lambda}\).
Absorptivities and emissivities of most natural surface materials are high in the Long-wave, but not for gases.
- The ‘atmospheric window’ is a region in the Long-wave where few gases interfere - often transparent.