Tuesday Aug. 29, 2017
Lucius
"Madness"
(4:30), "Two
of Us on the Run" (4:51), "Turn it
Around" (3:48), "Goodbye"
(2:42), "Free
As a Bird" (3:20), "How Loud Your
Heart Gets" (6:58)
Air Pollutants
Air Pollution is a serious health hazard in the US and around
the globe (click here to download a
copy of the information below). The
lists below give some idea of how serious a threat it is.
The top list shows the external or
environmental agent that causes death. The second list
is the physiological or internal bodily function that
ultimately leads to your demise. Keep in mind that many
of these numbers are difficult to measure and some may contain
a great deal of uncertainty (they are also somewhat out of
date). The row that is highlighted, toxic agents,
contains estimates of deaths caused by indoor and outdoor air
pollution, water pollution, and exposure to materials such as
asbestos and lead both in the home and at the work
place. It is estimated that 60% of the deaths are due to
exposure to particulate matter, something that we will examine
in a little more detail on Thursday.
Air pollution is a serious hazard
worldwide. Interestingly indoor air pollution is, in many
places, a more serious threat than outdoor air pollution.
In that regard, here's
a link to an article titled "Open-Fire Stoves Kill
Millions. How Do We Fix It?" (it appeared in the Dec. 2012
issue of Smithsonian Magazine).
I'm not sure how the researchers determine that 150,000
people are killed by climate change every year.
The Blacksmith Institute
(now Pure Earth Blacksmith Institute) listed the Top 10 polluted
places in the world in a 2007 report. The report has
received a lot of worldwide attention. Click here
to see a 2013 update of the list. These lists are included
just in case you are interested. And note all types of
pollution are considered, not just air pollution.
A summer or two ago I
heard mention of a recent study (ref)
that estimates air pollution kills about 4000 people per day
in China. Here's an
August 18 2015 article from the Washington Post that
discusses the study. Much of this is
particulate pollution which is something we'll cover next
week. In addition to being a health hazard, particulates
can have a dramatic effect on visibility.
_______
We will be looking at four air pollutants this week
and we really be able to see some of them. They're listed
below together with an idea of the number of main points you
should remember and understand about each.
Today's class will also feature a light
scattering demonstration. It's a fairly simple concept and
explains how/why we are able to see things like smog, clouds,
and particulate matter in the air. We will also produce
some photochemical smog in a demonstration Thursday probably
(safely confined in a glass bottle). You'll be able to see
the smog because it scatters light.
Carbon Monoxide (CO)
We'll start our section on air
pollutants with carbon monoxide. You'll find
additional information on carbon monoxide and other air
pollutants at the Pima
County Department of Environmental Quality website
and also at the US
Environmental Protection Agency website.
The material above is from page 7 in the photocopied
ClassNotes. We will mostly be talking about carbon
monoxide found outdoors, where it would only rarely reach fatal
concentrations. CO is a serious hazard indoors also where
it can (and does) build up to deadly concentrations (several
people
were
almost
killed
in
Tucson
in
December 2010 for example).
Between
1999 and 2010 an average of 430 people were killed per
year from unintentional, non-fire-related carbon monoxide
poisoning according to the Centers for Disease Control and
Prevention (ref).
Carbon monoxide is insidious, you can't smell it or see it
and it can kill you (Point 1).
Once
inhaled,
carbon
monoxide
molecules
bond
strongly
to
the
hemoglobin
molecules
in
blood
and
interfere
with
the
transport
of
oxygen
throughout
your
body.
The
article about carbon monoxide poisoning in Tucson mentions that
the victims were put inside a hyperbaric (high pressure) chamber
filled with pure oxygen. This must force oxygen into the
blood and displace the carbon monoxide molecules.
CO is a primary pollutant (Point
2 above). That means it goes directly from a
source into the air, CO is emitted directly
from an automobile tailpipe into the atmosphere for example.
The difference between primary and secondary pollutants
is probably explained best in a series of pictures.
The distinction between primary and
secondary pollutants is a relatively minor point.
Point 3 explains that CO is produced by incomplete
combustion of fossil fuel. Basically there isn't enough
oxygen. More oxygen and complete combustion would produce
carbon dioxide, CO2.
Because cars and trucks produce much of the
CO in the atmosphere in Tucson, special
formulations of gasoline (oxygenated fuels) are used during the
winter months in Tucson to try to reduce CO emissions. The
added ethanol has the effect of adding more oxygen to the
combustion process.
Vehicles are also fitted with a catalytic converter that
will change CO into CO2 (and
also NO into N2 and O2 and hydrocarbons into H2O and CO2).
In Pima County, vehicles must also pass an emissions test every
year to insure that the car is burning fuel as cleanly as
possible.
The photograph below at left shows the blue flame that results
from complete combustion of natural gas (methane) in a Bunsen
burner. The air holes on the side of the burner are open and
plenty of air (oxygen) is available during combustion. The
flames on a gas stove or the pilot light in a hot water heat or a
furnace should have this blue color. If the air holes are
closed, the flame turns yellow. There isn't enough oxygen in
this case. This incomplete combustion will produce more
carbon monoxide and also a lot of black soot (carbon). (source
of the photo)
Clean (complete) and dirty (incomplete)
combustion of natural gas
In the atmosphere CO concentrations peak on winter mornings (Point 4). The reason for
this is surface radiation inversion layers. They are most
likely to form on cold winter mornings.
When we say inversion layer (Point 5), we mean a temperature inversion, a
situation where air temperature increases with increasing
altitude. That's just the opposite of what we are used to
(you would expect it to be colder at the summit of Mt. Lemmon than
here in the Tucson valley). This produces stable atmospheric
conditions which means there is little up or down air motion.
The lack of vertical air motions means there is very
little vertical mixing in a stable air layer.
In the left figure above, notice how temperature increases
from 40 F to 50 F in the thin air layer next to the ground.
That's the inversion layer. Temperature then begins to
decrease as you move further up. That's what we normally
see. When CO is emitted into the thin stable layer during
the morning rush hour, the CO remains in the layer and doesn't mix
with cleaner air above. CO concentrations build.
Later in the day the ground and air in contact with the ground
warms. The inversion disappears and air at the ground mixes
with cleaner air above. The evening rush hour adds CO to the
air but it is mixed in a larger volume of air and the
concentration doesn't get as high.
Thunderstorms like you have been seeing this time of year
contain strong up and down air motions. Thunderstorms are an
indication of unstable atmospheric conditions.
Sulfur dioxide (SO2
)
We'll turn now to another of the air
pollutants, sulfur
dioxide (SO2 ).
Sulfur dioxide is produced by the combustion of sulfur
containing fuels such as coal. Combustion of fuel also
produces carbon dioxide and carbon monoxide. People probably
first became aware of sulfur dioxide because it has an unpleasant
smell. Carbon dioxide and carbon monoxide are
odorless. That is most likely why sulfur dioxide was the
first pollutant people became aware of. Apparently
sulfur dioxide is one of the smells in a freshly struck match.
Volcanoes are a natural source of sulfur dioxide.
US NAAQS in the figure above stands for United States National
Ambient Air Quality Standards. Air with a
pollutant concentration that exceeds the NAAQS is considered
unhealthy. This is discussed further in an online Supplementary Reading section.
London-type smog
The inversion layer in this case lasted for several days and was
produced in a different way than the surface radiation
inversions we heard about when covering carbon monoxide.
Surface radiation inversions usually only last for a few hours.
The term smog, a contraction of smoke + fog, was invented to
describe a mixture of smoke and fog, something that was fairly
common in the winter in London. The 1952 event was an
extreme case. Now we distinguish between "London-type
smog" which contains sulfur dioxide and photochemical or "Los
Angeles-type smog" which contains ozone.
Most of the photographs below come
from articles published in 2002 and 2012, the
50th and 60th anniversaries of the event.
The dramatic drops in visibility are mostly being caused by
fog. Later in the semester we will learn that fog clouds
that form in "dirty" contained smoke particles can be thicker than
fog that forms in cleaner air.
The caption to this
photo from The Guardian reads
"Arsenal goalkeeper Jack Kelsey peers into the
fog.
The 'smog' was so thick the game was eventually
stopped."
|
The smog in this photo is the thickest I was able to
find. Visibility here is perhaps 10 or 20 feet.
(source
of this image)
|
|
|
|
Smog masks from this
reference
The masks would filter out the smoke but not the
sulfur dioxide gas
|
Even though it is a little off topic, here are
some interesting photographs
of early and mid 20th century London.
The sulfur dioxide didn't
kill people directly. Rather it
would aggravate an existing condition of some
kind. The SO2 probably also
made people susceptible to bacterial infections
such as pneumonia. Here's
a link that discusses the event
and its health effects in more detail.
The Clean
Air Act of 1956 in England reduced smoke
pollution and emissions of sulfur dioxide.
Air
pollution disasters involving sulfur dioxide have also
occurred in the US. One of the deadliest events was in
1948 in Donora, Pennsylvania.
The reference
material that contained this photographed stated
"This eerie photograph was taken at noon on
Oct. 29, 1948 in Donora, PA as deadly smog enveloped the
town. 20 people were asphyxiated and more than 7,000
became seriously ill during this horrible event."
The photograph below shows some of the mills that were operating
in Donora at the time. Not only where the factories adding
pollutants to the air they were undoubtedly adding hazardous
chemicals to the water in the nearby river.
source
of this photo
The US passed its own
Clean Air Act in 1963. There have been several
major revisions since then. The EPA began
in late 1970 (following an executive order signed by President
Nixon)
"When Smoke Ran Like Water,"
a book about air pollution is among the books
that you can check out, read, and report on to
fulfill part of the writing requirements in this
class (though I would encourage you to do an
experiment instead). The author, Devra
Davis, lived in Donora Pennsylvania at the time
of the 1948 air pollution episode.
Scattering (splattering) of light
We spent the next portion of today's class learning about the
scattering of light. You are able to see a lot of
things in the atmosphere (clouds, fog, haze, even the blue sky)
because of scattering of light. We'll try to make a cloud of
smog in class on Thursday. The individual droplets making up
the smog cloud are too small to be seen by the naked eye.
But you will be able to see that they're there because the
droplets scatter light. That's true also of the little water
droplets that make up a cloud. So we need to take some time
for a demonstration to see exactly what light scattering is.
The figures below can be found on pps 107a - 107b in the
ClassNotes.
In the first part of the demonstration a narrow beam of intense
red laser light was directed from one side of the classroom to the
other.
We're looking down from above in the the figure
above. Neither the students or the instructor could see
the beam of light. To see the laser light some of it
would need to be traveling toward you rather than from one
side of the room to the other.
The instructor would have been able to see
the beam if he had stood at the end of the beam of laser light
where it hit the wall and looked back along the beam of light
toward the laser. The insert at upper right shows what
the instructor would see, a bright spot of light originating
at the end of the laser tube itself. That wouldn't have
been a smart thing to do, though, because the beam was strong
enough to possibly damage his eyes (there's a
warning on the side of the laser).
Everybody was able to see a bright red spot where the laser
beam struck the wall.
This is because when the intense beam
of laser light hits the wall it is scattered (I think
splattered is a more descriptive term). The
original beam is broken up into a multitude of weaker
rays of light that are sent out in all directions.
There is a ray of light sent in the direction of every
student in the class. They see the red spot of
light because they are looking back in the direction the
ray came from. It is safe to look at this
light because the original intense beam is split up into
many much weaker beams.
Next we clapped two erasers together so that some
small particles of chalk dust fell into the laser
beam.
Now instead of a single spot on the wall, students saws lots of
points of light coming from different positions along a straight
segment of the laser beam. Each of these points of light was
a particle of chalk, and each piece of chalk dust was intercepting
laser light and sending light out in all directions. Each
student saw a ray of light coming from each of the chalk
particles. With a cloud of chalk dust you are able to see
segments of the laser beam.
We use chalk because it is white, it will scatter rather than
absorb visible light. What would you have seen if black
particles of soot had been dropped into the laser beam?
In the last part of the demonstration we made a cloud by pouring
some liquid nitrogen into a cup of water. The cloud droplets
are much smaller than the chalk particles but are much more
numerous. They make very good scatterers.
The beam of laser light was very bright as
it passed through the small patches of cloud. The cloud
droplets did a very good job of scattering laser light.
So much light was scattered that the spot on the wall
fluctuated in intensity (the spot dimmed when lots of light
was being scattered, and brightened when not as much light was
scattered). Again the insert shows what you would see if
you stood at the wall and looked back toward the laser.
Some of the light passes through the cloud so you would still
be a spot of red light, but it would be weaker and more
diffuse. Then you would see red scattered light coming
from the cloud surrounding the beam of laser light.
Here's a side view photo that I took back in my office.
The laser beam is visible in the left 2/3 rds of the picture
because it is passing through cloud and light is being scattered
toward the camera. There wasn't any cloud on the right
1/3rd of the picture so you can't see the laser beam over near
Point 1.
The air molecules in the room are actually scattering laser
light but it's much too weak for us to be able to see it.
When a stronger light source (sunlight) shines through much more
air (the entire atmosphere) we are able to see the scattered
light. The blue light that you see when you look at sky is
sunlight being scattered by air molecules. This is the
topic of another 1S1P
assignment.
