637Lesson17

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Transcript 637Lesson17 

Lesson17
Heterogeneous and cloud processes
Heterogeneous and cloud processes
• Wide range of physical and chemical of
substrate surfaces for heterogeneous reactions
to take place.
• Clouds have approximately 1 billion water
droplets per cubic meter.
• Lots of surface area for reactions to take place.
• Both ice (cirrus) and water clouds exist.
• Other substrates are less abundant but are still
significant e.g. sulfates, black carbon, organic
compounds, sea salt.
Heterogeneous and cloud processes
•
(1)
(2)
(3)
(4)
Four simple categories of reactions can be
identified that create aerosols and droplets,
and occur on or in them
Condensation of a single component –
homogeneous-homonuclear reaction
Reaction of more than one gas to form a new
particle – homogeneous-heteromolecular
reaction
Reaction of gases on a pre-existing surface –
heterogeneous-heteromolecular reaction
Reactions within the particles themselves
Heterogeneous and cloud processes
• Type 1. Aggregation of water molecules to form a droplet
or ice crystal. Needs a condensation nucleus to be
efficient.
• Type 2. Two or more gases form a condensable product
NH3gas + HNO3gas → NH4NO3solid
note that the reaction of the gases on an existing particle
is more likely (type 3)
• Type 3. Sometimes known as aerosol scavenging.
Clouds and raindrops have a major effect on gas phase
species through this process. Rainout – cloud droplets –
is more important than washout – raindrops – because of
the greater surface areas and lifetime. Water soluble
species e.g. acids, acid anhydrides, and peroxide are
particularly susceptible to this process.
Heterogeneous and cloud processes
• Type 4. includes chemical reactions that occur within the
aerosol itself to form particles of changed composition.
• An example is the oxidation of SO2 to sulfate ions in
clouds.
• These are multi-phase reactions. Involve transfer from (
and back to) the gas phase.
• Condensed phase is almost always liquid, since diffusion
in solids is slow.
• Clouds also provide an active chemical medium for
aqueous-phase reactions.
• For example key compounds in tropospheric chemistry
such as HO2 and N2O5 are highly soluble. As the
reactions involving these species are usually irreversible
the species continue to be dissolved in the liquid.
Heterogeneous and cloud processes
• The formation of HNO3 from N2O5
N2O5 + H2O → HNO3 + HNO3
The gas-to-aqueous transfer of N2O5 is limited by gasphase diffusion (Henry’s Law) while the reaction is so
fast that the dissolution of N2O5 can be considered as
irreversible.
• Cloud reactions further influence the oxides of nitrogen
by removing the NO3 radical. Because the radical has a
long lifetime it can be incorporated into cloud water. NO3
is not particularly soluble in pure water, but if the water
contains chlorine ions (e.g. near or over the oceans)
then:
NO3 + Cl- → NO3- + Cl
Note that this reaction releases the Cl atom.
• A similar sequence is also responsible for the removal of
the PAN molecules.
Measurements
Tropospheric measurements
• Both in-situ and remote measurements are made for
tropospheric species.
• Earliest in-situ measurements were for ozone.
Schonbeim measured ozone by noting that ozone
released the iodine atom when reacting with potassium
iodide. Known as a chemical sensor.
• Present chemical detectors include
(1) gas chromatography.
(2)`Chemiluminescence
(3) Resonance fluorescence
(4) Mass spectroscopy
(5) Absorption and emission spectroscopy
Chemiluminescence
Chemiluminescence
• Certain exothermic chemical reactions
lead to the emission of light.
• For example:
NO + O3 → NO2 + hν
NO2 + luminol → hν
• By converting other N species to NO one
can broaden the use of the
chemiluminescence technique to other
species, e.g. NOY, HNO3, or PAN
Resonance fluorescence
Resonance fluorescence
• Spectroscopy is at the heart of all remote sensing
techniques, however it can also be used as an in-situ
technique.
• In resonance fluorescence one excites the atom or
molecule at a resonant frequency – principally to
increase the absorption cross section. Has been used to
detect the OH radical using a laser as the excitation
source.
• However this can cause a problem as the same
wavelength that excites the OH also dissociates the
ozone molecule
O3 + hν → O2* + O(1Δg)
O(1Δg) + H2O → OH + OH
• Hence the measurement can actually produce OH.
Resonance fluorescence
Absorption
Absorption
• Ozone can be measured by passing the air through a
long-pathlength chamber and measuring the absorption
at 253.7 nm.
• 253.7 nm is emitted by a quartz envelope mercury lamp.
• Long path lengths are generated by placing mirrors at
the ends of the chamber to produce multiple reflections
• Can also be used to measure CO (in the infra-red)
• If we use the sun as the source then we can measure
the column amount of the gas. Ozone and sulfur dioxide
are measured using this technique.
• Dobson spectrophotometer measures ozone at
ultraviolet wavelengths
LIDAR techniques
• Light detection and ranging
• Uses pulses of laser radiation.
• Time of return of the pulse gives the altitude of the
fluorescence.
• For resonance fluorescence – the strength of the
returned signal gives the density of the species at that
altitude. Used to measure altitude profiles of aerosols.
• For absorption the strength of the returned signal gives
the optical path to and from that altitude. By using two
wavelengths, one strongly absorbed by ozone, the other
not, one can cancel out the effect of aerosols.