Class objectives: Cover some of the major topics in Environmental Chemistry Energy Atmospheric...
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Transcript of Class objectives: Cover some of the major topics in Environmental Chemistry Energy Atmospheric...
Class objectives:
• Cover some of the major topics in Environmental Chemistry
• Energy
• Atmospheric Compartment
• Water compartment
• Soil
• Polynuclear Aromatic HC (PAHs)
• Dioxins
• Ketones
• PCBs
• CFCs
• DDT
• O3, NO2, aerosols, SO2
1. Some examples of environmental chemicals
Toxic loads
• Scientists have hypothesized that the fetus is sharing the mother’s toxic load, and may actually provide some protection to the mother by reducing her internal exposure.
• Children get 12% of their lifetime exposure to dioxins during the 1st year.
• Their exposure is 50 times greater than an adult during a very critical developmental period.
• Firstborns from dolphins off the coast of Florida usually die before they separate from their mothers
Mother’s milk
• Human babies nursed by mothers with the highest PCB contamination levels in their milk are afflicted with more acute ear infections than bottle fed Inuit babies.
• Many of these children don’t seem to produce enough antibodies for childhood vaccinations to take.
PCBs and lower intelligence
• There is evidence of lower intelligence in babies exposed to PCBs.
• In adults, a blood-brain barrier insulates the brain from many potentially harmful chemicals circulating through the body
• In a human child this barrier is not fully developed until 6 months after birth.
2. Energy
SO what is a joule??Force = mass x acceleration; f = m x a
a = velocity / time = dv/dt
velocity = distance / time; a= distance / time2
Work = force x distance
W = f x d
W= m x a x d and W = m x d2 /t2
Work and energy have the same units
a joule is defined as accelerating 1 kg of mass at 1 meter/sec2 for a distance of 1 meter
A watt is a unit of power = 1 joule/second or energy/time
how long will the oil last??
1980 estimate of reserves Oil 1x1022 J
1980 estimate of oil usage /year1.35x1020 J/year
Estimate the # years of oil left if we used at the above rate from 1980 to 1990 and 2x’s the 1980 rate after
1990 = 3x; we estimated ~50 to 80 years
We used more recent data in class.
Fuel energyWhen we burn a fuel where does the energy reside?
Let s take hydrogen in water as an example. If we were to react H2 with O2 to form water, we would 1st have to break the hydrogen bonds and the oxygen bonds
This takes energy; in the case of H2 it takes 432 kJ/mole (~100,000 calories/mole) for H2 2H.
How many days of food will supply you with 100,000 calories?
To break O2 to O. (O2 2O.) requires494 kJ/mol
When when water forms, however, we get energy back from the formation of H2O because new bonds are formed. Which ones??
Combustion energies from different fuels (kJ) react. per per per moles
heat mole mole gram CO2 perkJ O2 fuel fuel 1000kJ
hydrogen 482 482 241 120 02H2+O2 2H2O
Gas 810 405 810 52 1.2CH4 + 2O2CO2 +2H2O
Petroleum 1220 407 610 44 1.6 2 (-CH2-)+ 3O22CO2 +2H2O
Coal 2046 409 512 39 2.04 (-CH-)+ 5O24CO2 +2H2O
Ethanol 1257 419 1257 27 1.6 C2H5OH + 3O22CO2 +3H2O
wood 447 447 447 15 2.2(-CHOH-) + O2CO2 +2H2O
3. Basic concepts• Where does pV=nRT come from?
• At standard state can you calculate R?
• A+B C+D
ln Keq =-H/R x 1/T + const.
))((
))((ln
BA
DCo
bp
ppRTG
4. The atmospheric compartment
Two important features the atmosphericCompartment aretemperature and pressure
Why does the temperature normally decrease with height in the troposphere and increase with height in the stratosphere??
The pressure or force per unit area
decreases with increasing altitude
The decline in pressure (P) with altitude is approximately = to
log P= - 0.06 (z); where z is thealtitude in km and P is bars
How thin is the air at the top of Mt. Everest?Mt. Everest is 8882 meters high or 8.88 km high
log P = -0.06 x 8.88
P = 10-0.06x 8.88 = 0. 293 bars
Assume there are 1.01bars/atm.
This means there is < 1/3 of the air
Air that contains water is not as heavy and has a smaller lapse rate and this will vary with the amount of water
If the air is saturated with water the lapse rate is often called s
Near the surface sis ~ 4 oK/km and at 6 km and –5oC it is ~6-7 oK/km
The quantity d is called the dry the dry adiabatic lapse rate
At the equator air is heated and rises and water is evaporated.
As the air rises it cools producing large amounts of precipitation in equatorial regions.
Having lost its moisture the air mass moves north and south.
It then sinks and compresses (~30oN and S latitude) causing deserts
How does air circulate
The mean residence time (MRT) can be expressed as:
MRT = mass / flux
where flux is mass/time
If 75% of the mass/year in the stratosphere comes from the troposphere
1
MRT = ----------------- = 1.3 years– 0.75/year
Mt. Pinatubo in the Philippines erupted in June 1991, and added a huge amount of SO2 and particulate matter the stratosphere. After one year how much SO2 was left?
For a 1st order process C= Coe -1 year/ MRT
C/Co= e -1 year/ MRT = e -1/1.3= 0.47 or ~ 50%
in 4 years, C/Co= e -4 years/1.3 years = ~5%
What happened to global temperatures after the Pinatubo eruption?
A lot of SO2 was injected into the atmosphere
SO2 forms fine sulfate particles that reflect light back into the atmosphere and this cools the upper troposphere
5. What is Global Warming and how can it Change the Climate?
How fast are green house gases increasing???
time trace for the concentration of carbon dioxide from 1958-1992 at Mt. Mauna lowa Hawaii
Why does it oscillate up and down as it generally goes up??
How fast is Global Warming Occurring?
The rate of global warming over the next century may be more rapid than any temperature change that has occurred over the past 100,000 years!!!
This will cause major geographical shifts in forests, vegetation, and cause significant ecological disruption
1979 perennial Ice coverage Nat. Geographic, Sept 2004)
2003 perennial Ice coverage
Doubling Emissions of CO2
Often discussed are the effects of doubling CO2
concentrations from pre-industrial times (2xpre-Ind. CO2=550 ppm)
Some times predications are made with the assumption of CO2 doubling or even quadrupling.
On the next slide you will see world wide emissions using different assumptions.
Including Particles in Global Models
Fine particles, especially sulfate particles resulting from SO2 emissions from coal, combustion can reflect light from the sun and actually cause a negative temp. effect
The next 2 picture from a global circulation model (GCM by Bob Charleston, UW-Wash, USA), shows a cooling effect in the industrialized world.First without considering particles then with
red= +2oC, yellow =+3oC, blue = +10C
red= +2oC, yellow =+3 oC, blue = +10C
red= +2oC, yellow =+3 oC, blue = +10C
6. Kinetics: 1st order reactions
A ---> B
-d [A] /dt = krate [A]
- d [A]/[A] = kratedt
[A]t= [A]0 e-kt
ln[ ] ,,A k tA t
A t t 0
Some time vs conc. data
H
r Conc [A] Ln[A]
0 2.718 1
0.3 2.117 0.75
0.6 1.649 0.50
0.9 1.284 0.25
1.2 1.000 0.00
1.5 0.779 -0.25
1st order plot
-0.4
-0.2
0
0.2
0.4
0.6
0.8
1
1.2
0 0.5 1 1.5 2
time in hours
ln[A
]
A plot of the ln[conc] vs. time for a1st order reaction gives a straight line witha slope of the 1st order rate constant.
ln [A]/[A]o=-k t1/2 ; ln2 /k =t1/2
2nd order reactions
A + B products
dA/dt = k2nd [A][B]
If B is constant
kpseudo 1st = k2nd [B]
kpseudo 1st = k2nd [B]
ln2 /k =t1/2
1. constant OH radicals in the atmosphere
kpseudo 1st = k2nd [OH.]
7. Stratospheric o3 The Stratosphere begins about 10k above the surface of the earth and goes up to 50k The main gases in the stratosphere, as at the surface, are oxygen and nitrogen uv light of low wave lengths ( high energy) split molecular oxygen (O2 )
to split oxygen O2 O. + O.
requires 495 kJ mole-1 of heat (enthalpy) What wave length of light can do this?? Let’s start with h = E, where h is Planck’s constant and is the frequency of light and E is the energy associated with one photon.
And, = c where c is the speed of light and is the wave length of light Combining we can solve for the wave length that will break apart oxygen at an enthalpy of 495,000 J mole-1
= h c/ E
If the value of Planck’s constant is6.62 10-34 joules sec c = 2.9979 x108 m sec-1
= h c/ E = 241 nmcan you verify this calculation? Hint energy E is for one photon??
Paul Crutzen in 1970 showed that NO and NO2
react catalytically with O3 and can potentially remove
it from the stratosphere.(he get’s a nobel prize for this in 1995)
NO + O3 NO2 + O2
NO2 + O. -> NO + 2O2
So where would NO come from?? SST’s
CCl3F + uv Cl. + .CCl2F
but the free chlorine atom can react with O3
Cl. + O3 ClO. (chlorine oxides) + O2
what is really bad is that
ClO. + O. Cl. + O2
Remember that:
O.+ O2 O3 (Ozone)
It is estimated that one molecule of chlorine can degrade over 100,000 molecules of ozone before it is removed from the stratosphere or becomes part of an inactive compound.
Molina found in 1985 that HCl could be stored on the surface of small nitric acid particles in polar stratospheric clouds (PSC).
The HCl then just had to wait for a ClO-NO2 to hit the particle
particle Cl2
Cl2 + uv Cl. + Cl.
These nitric acid particles form under extremely low temperatures in polar stratospheric clouds
Cl2
ClO-NO2
HCl
8. What are aerosols?• Aerosols are simply airborne particles
• They can be solids or liquids or both
• They can be generated from some of the following sources:
1. combustion emissions2. atmospheric reactions3. re-entrainment
Cooking stir-fried vegetables: Kamens house, 1987, EAA data
Anthropogenic sourcesPrimary aerosol
Industrial particles 100x 1012 g/yearsoot 20forest fires 80
Secondary aerosolssulfates from SO2 140organic condensates 10nitrates from NOx 36
sum of Anthropogenic 390 x1012g/year
sum of natural sources 3070 x1012g/year
What are some of the terms used to describe aerosols?
• Diameters are usually used to describe aerosol sizes, but aerosols have different shapes.
Often particles are sized by their aerodynamic diameter
• The aerodynamic diameter of a particle is defined as the diameter of an equivalent spherical particle (of unit density) which has the same settling velocity.
• It is possible to calculate the settling velocity of a spherical particle with a density =1
Fresh wood soot in outdoor chambers (0.5 m scale
Gas Particle Partitioning
particle
toxic gas
Langmuirian Adsorption (1918)
gas
surface
• = fraction of total sites occupied• Rateon= kon (Pg) (1- );• Rateoff= koff ;• kon/koff= Keq
Langmuirian Isotherm
•
• if Keq Cgas<< 1; = Keq Cgas
gaseq
gaseq
CK1
CK
Yamasaki et al.(1982)• Langmuirian adsorption•
• Assumes total # sites TSP (particle conc)
• log Ky = -a(1/T)+ b
Kgas
part TSPy [ ]
[ ] /
Yamasaki (1982)• Collects Hi-vol filters+PUF• Analyzes for PAHs
filter
PUF
log Ky
1/Tx1000
BaA
Partitioning & uptake by the lungs
• Nicotine (Pankow’s group)
Killer Particles
Mortality vs. particle exposure
2.5 m particle conc. in g/m3
10 20 30 40
mortality ratio
1.0
1.1
1.2
1.3
• On a mass basis urban fine particles may be more toxic than cigarette smoke
Samet et al. at UNC exposed human airway epithelial cells to residual oil fly ash (ROFA) particles
• cells secreted prostaglandins
• Prostaglandins are a class of potent inflammatory mediators which play a role in inflammatory, immune and functional responses in the lung