Topic 2 - Stratospheric Chemistry

Question 1

What were the features of the very early atmosphere?

Answer 1

It consisted of H₂ and He.

There was enhanced solar wind, which removed most of the Earth’s atmosphere.

There were additional losses from overcoming the gravitational field.

Question 2

What were the features of Earth’s second atmosphere?

Answer 2

Second atmosphere was formed from rocks outgassing.

Prebiotic atmosphere containing mainly of H₂, CH₄, NH₃, H₂S, H₂O, CO, CO₂, NO₂ and SO₂.

Question 3

What were the features of the prebiotic atmosphere?

Answer 3

The prebiotic atmosphere was transparent to radiation down to wavelengths <= 200 nm.

Strong, short wavelength UV radiation field present on the surface of the Earth.

UV radiation can damage the molecules of life, which means that early life must have been UV robust or protected from UV radiation.

Very little O₂ and thus reducing atmosphere.

Question 4

What were the features of early life?

Answer 4

Initial formation of the molecules of life (amino acids) occurred as a result of lightning and UV impingent on the early atmosphere.

Organisms exist today which can use CO₂, H₂, water, organic molecules, various ions and sunlight as energy sources.

Question 5

What were the features of the Great Oxygenation Event?

Answer 5

Bacteria evolved which could produce a range of different molecules, leading to the accumulation of nitrogen.

Early organisms did produce oxygen but not enough for it to build up as it reacted to form various minerals in rocks, such as iron oxides.

About 2.5 billion years ago the ‘Great Oxygenation Event’ occurred after the rocks became saturated with oxygen.

Oxygen eventually accumulated in the atmosphere.

Question 6

How did ozone concentration increase?

Answer 6

The concentration of ozone is linked with the concentration of oxygen.

Question 7

What are three classifications of UV light and their wavelengths?

Answer 7

UV-A (320-400 nm)

UV-B (290-320 nm)

UV-C (200-290 nm)

Question 8

How does oxygen absorb UV radiation?

Answer 8

Oxygen absorbs UV radiation below 195 nm (Herzberg continuum).

There is also a weak absorption band above 200 nm (Schumann-Runge band).

Question 9

How does oxygen dissociate when absorbing UV light with a wavelength of < 175 nm?

Answer 9

O₂ → O(³P) + O(¹D)

Question 10

How does oxygen dissociate when absorbing UV light with a wavelength of between 175 nm and 242 nm?

Answer 10

O₂ → 2O(³P)

Question 11

How does the O¹D state decay?

Answer 11

By colliding with other molecules in the atmosphere.

It will relax into a ³P state.

Question 12

How does the O atom production rate change with altitude?

Answer 12

The concentration of O₂ decreases exponentially with altitude.

The O₂ photolysis rate increases with altitude due to increased UV intensity.

This causes an optimum altitude for O atom production which is in the stratosphere.

Question 13

How does ozone interact with radiation?

Answer 13

Ozone absorbs UV radiation, particularly strongly below 250 nm.

At λ < 1180 nm: O₃ → O₂ + O.

At λ < 411 nm: O₃ → O(¹D) + O₂(³Σ_g^-)

At λ < 310 nm: O₃ → O(¹D) + O₂(¹Δ_g)

Question 14

What are the four stages of the Chapman Mechanism?

Answer 14

1) At λ < 242 nm: O₂ → O + O

2) O + O₂ –M→ O₃

3) At λ < 1180 nm: O₃ → O₂ + O

4) O + O₃ → 2 O₂

Question 15

How accurate is the Chapman cycle at predicting ozone concentration in the atmosphere?

Answer 15

It overpredicts ozone concentrations by a factor of two at all altitudes.

This is because it only models the effects of oxygen and nitrogen and does not include the effects of trace gases.

Question 16

How does ozone lifetime vary with altitude?

Answer 16

Ozone lifetime decreases with ascending altitude from a few hours at the top of the stratosphere to more than a year at the bottom of the stratosphere.

In the troposphere, ozone could have a very long lifetime in addition to being a potent greenhouse gas.

Question 17

What are the three catalytic loss cycles?

Answer 17

The HO_x cycle.

The NO_x cycle.

The HalO_x cycle.

Question 18

What are the stages of the HO_x cycle?

Answer 18

O₃ + OH → HO₂ + O₂

HO₂ + O → OH + O₂

Overall: O₃ + O → 2O₂

Question 19

What are the stages of the NO_x cycle?

Answer 19

O₃ + NO → NO₂ + O₂

NO₂ + O → NO + O₂

Overall: O₃ + O → 2O₂

Question 20

What are the stages of the HalO_x cycle?

Answer 20

O₃ + Hal → HalO + O₂

HalO + O → Hal + O₂

Overall: O₃ + O → 2O₂

Question 21

What is the catalytic chain length?

Answer 21

The number of times a cycle can be repeated before the catalyst is lost.

Question 22

What are reservoir species?

Answer 22

Compounds that temporarily lock up certain atoms.

This can form a holding cycle where a proportion of the atoms are always locked up.

Around 5-10% of NO_x is held in a holding cycle.

Question 23

What is a null cycle?

Answer 23

A null cycle does not destroy odd oxygen.

They are in competition with catalytic loss cycles.

For example, NO₂ can be used as a catalyst to convert ozone into oxygen and an O atom.

Question 24

How accurate is the ozone concentration model with the Chapman cycle and catalytic loss cycles added?

Answer 24

Relatively accurate.

Question 25

What is a correlation between CFC mixing ratios and ozone concentration?

Answer 25

There is a strong correlation of a decrease in total ozone column density during Antarctic spring with an increase in the CFC mixing ratio.

Question 26

How does CFC concentration change with altitude?

Answer 26

There is a rapid decrease of CFC concentration at higher altitudes which suggested that they were being photolysed.

Question 27

What are the features of Antarctic meteorology?

Answer 27

Antarctica has unique meteorology.

The Southern Polar airmass is decoupled from the rest of the atmosphere in Antarctic winter due to the formation of a polar vortex.

The stratosphere has a very low temperature which provides unique conditions for chemical reactions to take place.

Question 28

What are the features of polar stratospheric clouds?

Answer 28

At low stratospheric temperatures, high altitude polar stratospheric clouds can form.

At T < 200 K, hydrates of nitric acid cluster around a sulfate aerosol core initiating polar stratospheric cloud type I formation.

At T < 190 K, water freezes and initiates polar stratospheric cloud type II formation.

Question 29

How can polar stratospheric clouds affect atmospheric chemistry?

Answer 29

Ice particles inside the cloud provide a catalytic environment for halogen gas release. This proceeds through a two-step process (adsorption and surface reaction) which are significantly faster than the direct gas phase reaction.

Question 30

What are the catalytic reactions that occur in polar stratospheric clouds?

Answer 30

Slow (gas phase)

ClONO_{2 (g)} + HCl _(g) → Cl_{2 (g)} + HNO_{3 (g)}

Fast (heterogenous, on ice surface)

HCl _(g) –Ice Surface→ H₃O⁺ _(ads) + Cl^- _(ads)

ClONO_{2 (g)} + Cl^- _(ads) –Ice Surface→ Cl_{2 (g)} + NO₃^- _(ads)

Question 31

Why is ozone loss seasonal?

Answer 31

NO_x remain trapped on and in the PSC particles as nitric acid hydrates. These grow and eventually settle out of the atmosphere which results in a NO_x depletion.

This means less is available to use in holding cycles and so Cl₂, ClO, and (ClO)₂ accumulate in the atmosphere in the winter.

When the sun returns in spring, the chlorine compounds photodissociate into Cl. As the stratosphere has been denitrified, holding cycles are not significant so the effect is enhanced.

Question 32

What is ODP?

Answer 32

Ozone Depletion Potential.

It is a relative scale to quantify the effectiveness of ozone depleting substances to deplete stratospheric ozone when compared with CFCl₃.

Question 33

What is ODP dependent on?

Answer 33

The number of halogen atoms, tropospheric lifetime and photolysis efficiency.

Question 34

What does tropospheric lifetime depend on?

Answer 34

How reactive a compound is with OH radicals. Longer lifetime results in transport to stratosphere and possible perturbation of the ozone layer.

Question 35

What does photolysis efficiency depend on?

Answer 35

Photolysis efficiency increases with absorptions at longer wavelengths. Heavier halogens and multiple halogen substituted chemicals have longer wavelength absorption.

Question 36

What are the features of OH radical reactivity?

Answer 36

Partially halogenated species have hydrogen which can react with OH radicals. This reaction proceeds by H atom abstraction which initiate radical chemistry and degradation.

Unsaturated halogenated species can easily add OH radicals and thus have high reactivity.

Question 37

What are the features of bromine containing molecules in terms of ODS?

Answer 37

Bromine containing molecules absorb at longer wavelengths and are more susceptible to photolysis at lower altitudes. At lower altitudes, catalytic ozone losses are enhanced.

Additionally some loss reactions are slower.

This catalytic activity relative to Cl, given the symbol α, can be up to 60 times higher.

Question 38

What is equivalent effective stratospheric chlorine?

Answer 38

The sum of mixing ratio of various compounds weighted by the number of halogen atoms, by a factor describing halogen release or α in the case of bromine containing compounds.

Question 39

How are ODP and GWP linked?

Answer 39

Molecules with high ODP also have high GWP. This is because they have a long tropospheric lifetime and infrared absorption in the ‘atmospheric window’ region.

Question 40

What is stratospheric cooling?

Answer 40

Due to the increased temperature of the troposphere, the troposphere extends to a larger altitude. Additionally, increased loading of tropospheric CO₂ and H₂O into the stratosphere has a radiative cooling effect.

Overall, this has led to the stratosphere cooling.

Question 41

How is global stratospheric ozone affected by stratospheric cooling?

Answer 41

Lower stratospheric temperature favours more PSC formation and heterogenous losses of ozone.

Higher concentrations of H₂O and CH₄ in the stratosphere because of the warmer troposphere can enhance the HO_x catalytic losses.

Airplanes release vast amounts of H₂O into the lower stratosphere enhancing PSC formation.

Question 42

How can geoengineering be used to combat climate change?

Answer 42

Aerosols can be injected into the stratosphere to increase the albedo of the planet. However, possible ozone losses need to be considered.