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Optical and chemical properties of roadside aerosols
The Science
Elsevier
AND
CHEMICAL
CLARKE
and
Department
of
B.V..
131-110 - Printed in The
Amsterdam
PROPERTIES
I.
131
59 (1987)
Enuironment,
Publishers
OPTICAL
A.G.
of the Total
Science
OF ROADSIDE
Netherlands
AEROSOLS
PAPAPANAYOTOU
Fuel
and
Energy,
Leeds
University,
Leeds,
LS2.9JT.
SUMMARY Roadside aerosols have been monitored by a variety of techniques. Optical reflectance of Whatman No.1 filters gave the British Standard smoke value. The optical absorption coefficient was measured by the integrating plate method after collection on Nuclepore filters. As expected there is a good correlation between optical absorption and smoke concentrations but a somewhat poorer correlation of these values with the mass concentration determined gravimetrically. Tc distinguish between local traffic emissions and the general urban background simultaneous monitoring was undertaken at a rooftop site away from the read. The specific absorption coefficient values were higher at the roadside than on the rooftop reflecting the higher proportion of carbonaceous material near to traffic. To assess the importance of the elemental and organic carbon content of the aerosol to the optical properties, two further measurements were made. The fraction of volatile matter in the aerosol was determined bv thermal desorotion and the carbon content of the non-volatile remainder was determined us-ing an elemental analyser. The fraction of volatile matter, which includes hydrocarbons and some inorganic species such as NH4N03. was found to be in the range 24-73X and to be slightly higher away from the road. The non-volatile carbon was found to be in the range 6-25:; by the road. The specific absorption increases with the fraction of non-volatile carbon.
INTRODUCTION It
is
well
known
relationship
to
particulate (based
total
mass
where
there
on
With
are
In
the
.3)
since ularly
the
similar
mass
coal
and
is to
lead
1 km from
004%9697/87/$03.50
much
77::
as
a factor
of
coal
are
darker
site
the
of
(ref.
i).
Ball
of
and
Hume,
Elsevier
the
of
carried
Publishers
London had
was
this
origin particA
the
correlation
of
at
the
Polytechnic There,
the
Hume
emissions,
out
B.V.
and
vehicles.
laboratory.
areas
particulate Ball
in
mass
in
between
engined
involving
authors'
Science
of
value. value
smoke the
Only
emissions
urban
the
2). equality
the
general diesel
cities,
(ref.
shade
airborne
underestimate
the
smoke
smoke
than
was of
the
a variable of
may
2-3 does
has
U.K.
l),
smoke
proportion
proportion
of
0 1987
of
lower
concentrations, the
of
ref.
determining
A much
a high that
atmosphere
valid
in
average
emissions there
concentration
smoke,traffic-generated role
on
measurement
mass
approximately
traffic.
traffic
analysis
than
in
smoke
calibration,
concentrations
that
where
as
Standard determined urban
1963
a significant
by
general
by
high
decline
found
British
the
remain
play
(ref.
less
original
concentration
contributed
total
the
measurements
matter
the
gravimetrically
matter.
value
two
that
the
smoke, in
the
Leeds
132 proportion
of
The elemental with
value
in
relation (see
absorption
Edwards
et
elemental
of
this
(Clarke
and
a major
have
work
side
the and
the
give
an
ed
the
be
obtained more
the
data
aerosol
is
been
obtained
has
particles
in
between was
value
the
the
atmos-
B.S.
smoke,
used
to
investigated
could
by
be
of of
the
local
variations
of
the
other
sources
but
very
fine
predict
in
the
aerosol. reported
aerosols
were
a minor
particles
of
optical
relative
the
made.
the
road-
matter these
of of
In
the
volatile
properties
on
Llm).
of by
Together
proportion
shown
0.1
made both
Some
effect
(s
been
been
main
the
concentrations
been
have the
been
only
have
measurements have
variations
of
roadside
mass
content
in
of have
measurements
Supplementary
from
although
coefficient
and
carbon
University
lo),
components
generated
paper,
the
Leeds
coefficients
presence
present
at 9 and
soluble
absorption the
the
levels
Freshly
the
level.
and
and
to
carbon,
(refs.
water
coefficient
rooftop
arising
of
and
smoke
of
also
of
correlation
the
scattering
11). on
suggesting
indication
emissions
on and
ref.
in
aerosol
aerosols
was
absorption at
previous
effect
reported
smoke,
studies
Morris,
scattering,
the
pollution
by
absorption
to
that
particulate
work
optical
5)
4).
An alternative,
amount
elemental
found
may
2). behaviour
The
ref. absorption
correlations
optical
7).
and
who
Ilhelan,
optical
(ref.
(ref.
6 and
(V.P.H. the
carbon.
characterised
on
good
emissions
refs.
8)
by
a considerable
coefficient (ref.
582
carbon) the
and
engine
atmospheric
emphasis
in
b,
in
al.
sub-Pm The
organic
describing
to
was
although
and
articles
optical
light
determined
coefficient
phere
data
smoke
primarily
parameter,
absorption
well
generated
carbon
(elemental
fundamental
the
is
(graphitic)
total
both
traffic
smoke
data
the
traffic
generat-
particles.
EXPERIMENTAL Measurements side
site
windm5 of
were
was m above
the
main
ground
routes
diesel-engined
5-102.
level
ca.
below.
representing The calibration
Most
samples
and
were
normal
given
in
is
to
50 m from air of
10
week
day
the
to
traffic
is
a high
some
main
roadfloor
lights
on
frequency
fraction parameters
one of
but
a re-
of
diesel
were
made
at
road.
velocities
are
duration
(8.30
hours
The
a first
cars,
overall
of
flow
through
petrol-engined The
vehicles.
1985.
in
There
addition
and
drawn
adjacent
centre.
measurements
media
concentration curve
in
October-December being
site
city
goods
30 m high
day-time, smoke
The
Simultaneous
sampling
period
samples
Leeds
of
is
shown
of
buses
vehicles
various
level.
out
the
curb,
passenger small
The
during
the
proportion
latively
rooftop
made
5 m from
indicated
in
a.m.-6.30
Table
1
p.m.),
conditions.
was
obtained
from
the
British
Standard
the
filter (ref.
reflectance 1).
Samples
using for
the the
133 absorbance
measurements
particle
mass
4503
on
concentrations
microbalance.
the
lowest
ed.
However,
concentration
A back-up
using the
two
filters
methods El,
trations
was
are
TABLE
weights of
when the
less
mass
times
in
Standard
smoke
particles
Mm was rate.
The
0.97,
were
made
agreement
N=65,
at
collect-
therefore
between
regression
line
mass
concen-
The
and
Lin,
absorbance Baker
duction
Charlson
light
particles age.
measurements
and
of
inated
by
tector.
on
Morris,
ref.
by
trap be an 80
the
used
This
the
Rate
involves
the
the
disk
at
24 80
by
than
filter
been
method of
caused
the
and
the
re-
cover-
light
given
of
the
monolayer
scattered
the
have
plate
measurement
less
forward
between
apparatus
2
filter
filter of
e/min.
1.5
integrating
a Nuclepore
intensity
opal
is of since
carbon
of not
content
elemental
the
filter
is
elim-
light
elsewhere
only
coarser
deposits
of
particulate on
the
combustion
since
particles,
the
preventing particles
on
were of
de(Clarke
tube
filter
the
573).
inside
(2
Use
surface
ug
been in
un-
re-
attempted
the
Impaction
This
a
filters
has
melts
using
technique
fibre
collected.
Model
made
this
matter glass
combustion. are
(Bendix particles
aerosols Application
collection in
straightforward
the
roadside
amounts
Although
precipitator and
of analyser.
large
form.
insertion
electrostatic g/min.
an
rather
compact
this some
using
of
the
author's
C.N.H.
requires
12)
Flow
11).
240C
in
followed (ref.
the
of
fortunately comnlended)
surface of
of
of
Measurements Elmer
12).
made
through
the
presence
Details
Pet-kin
(ref.
dependence the
were
transmission
collected Angular
Media
Whatman No.1, cellulose, 25 m clamps Nuclepore, 25 mm, 0.2 pm pore size Whatman, 37 nun, membrane filter, 1 pm pore size Whatman, 55 mm, glass fibre GF/F
Volatiles
ca.
of
off
methods.
Optical absorbance mass concentration Mass concentration
of
a Sartorius drops
Nuclepore-derived
Filter
British
not
with
the
error.
Measurement
may
obtain
1
E.iperimental
and
taken
ug
coefficient the
to
measurements
50
flow
that
used
were these
than
higher
confidence
seriously
also
concentration
(correlation
giving
not
Filter accuracy
ten
good
+ 4.84)
were
the
of at
filters
M,.
levels
measurement
membrane
M,,,=0.97
Nuclepore
process methods
was
therefore
has
a flow
of
removabl'a
and canmade
rate
of
134 aluminium the
cylinders
of
cylinders, in
the
weights
However,
sample
in
of
14).
remove
all
carbon
values
only
iculate
one
be
determined.
that
for
hears
of
this
reason
the
results
is
has
are
upper
(e.g.
does
not The
limits
reported
and
shown
as organic. as
a
elemental
techniques
regarded
total the
There
separating
identify
be
aerosol
than
devolatilisation
techniques
therefore
out
the
heating
analysis.
of
various
by
off
dried of
rather
removed
before
methods
and
N content
carbon
was
temperature
other
should
elemental carbon
24
low
electrostatic
material,
and
the
roof
was
used
before
s/min.)
and
The
then
species.
0f cl-,
rdo3-, so4
to
as
presented
simply
flow
flow
the
the
true
.non-
rates
ments
were
used
imply
particles
such
the
fractions
the
mass
NH4C1,
mass
there as
of
to will
volatile
were
be
used
roadside and
data
obtain
hydrocarbons soluble the
fibre
the
smoke
sampling
matter
samples
matter
collected
expected
that
& Nuclepore
efficiency In
dust.
is
filter
the
discussion
have
not
concentrations
itimasses
are
high measure
the
combined of
some
coarse of
been
hours
since the
filter for
24 and
and
glass
absolute
re-
for
of
It
carbonaceous to
before oven
water
particulate
for
175'C
amount
and
a greater
two at
the
monitored.
those
the
with
chromatography.
the
precipitator
assess
ion
of
roadside
the by
a vacuum
part-
the
preheated
a desicator in
of
leached
samples
accurately
as
includes
To
filters by
in
volatiles
NH4N03).
the
re-entrained
concentration
as
fractions
not
compared
that
lost
both
sampled were
175'C
amounts
rate
ranges
dried
at
at
flow
filters
was
heating
precipitator
as
rates
size
small
taken
same
clean
filter
after
remaining, 2- determined
from
The
matter
were The
particle
exposed
(e.g.
material
samples
the
loss The
organic
Results
that
the
producing
filters.
comparable.
weight
obtained.
inorganic
fibre
so be
weighing
filter
glass
should
weighing.
precipitator
additional using
(80
approaches
the
also
scraped
carbon'.
Having
was
can in
was boats
H and
comparisons
carbon
sample C,
various
the
deposit
the
for
the
that
and
platinum
was
175'C
The
gives
organic
in
obtained
carbon
volatile
interest
at
likely
the
normal
volatile
detailed
is
of
elemental
main the
oven
as
It
the
combustion
variability
carbon
ref.
of
a vacuum
deal
organic
the
bulk
diameter.
Analysis after
since the
great
to
a desicator.
ash
carbon,
mm internal
transferred
overnight and
37
results with
volatiles
and
carbon.
RESULTS Table British The dicated
2 summarises Standard roadside by
the
the
average
values
found
in
this
study.
Smoke smoke rooftop
values values
were
more
(averages
than 45
double and
the
18 ug
m
urban background -3 respectively).
inThe
135 TABLE
2
Average
Values
of
the
Parameters
Measured
-Parameter
Units
E S.
Smoke
u5t.m
Mass
Concentration
i-1g.m -3
Roadside
--
Absorption Coefficient
10-4m-1
Specific Coefficient
Abs.
Volatile
Fraction
Non-Vol. Fraction
Ionic
Non-Vol. Fraction
Carbon
Ash
mg2 -1
will
It
is
not
sum
to
100':.
relationship The
to
with
regression
be
lines
33
37.4
34
2.3
0.7
34
3.9
2.1
34
50
43
36
/J
17
22
27
that
the
gravimetrically
17
27
21
27
four
fractions
determined
t
2.41,
Corr.
Coeff.
0.86
Roof:
Smoke
= 0.70
M,
-
3.67,
Corr.
Coeff.
0.93
The
relationship matter
is
in
illustrated
the
table
in
Fig.
are M,
particulate
listed
mass
= 0.67
of
of Data Pairs
18.0
Smoke
1.
Ho.
73.2
Road:
Fig.
Value
,':
expected
the
Roof
45.5
c//L, rl,J
Fraction
N B.
-3
Value
of determined
British
Standard using
Nuclepore
smoke
with filters.
the
mass
concentration
1.
136
Fig.
2.
The
British
relationship
Standard In
both
mined
from
the
used
for collects
top
site
suspended
use
of
0.92)
which
aerosol.
roof
coefficient
between
road to
fact
The
values
the at
and
Coefficient average
greater
mass,
< 2.5
(corr.
con-
rate
method
sampling on
Pm)
been
method
the
same
gave
in
the
is coeffs.
points
roof-
smoke=0.55x
(ref.
10).
Our
significantly 0.86
composition
lie
near
2.3
and
0.7
as
shown
in
coefficient -4 -1 x 10 ni Fig.
2.
by
the
road
was
as of
the
respectively). The
three
The
regression
lines
less compared
the
line
to
roadside
along
ba
= 0.055
(smoke)
- 0.141,
corr.
coeff.
0.99
ba
= 0.047
(smoke)
- 0.160,
corr.
coeff.
0.97
of
ba
clearly
physical
property
aerosol.
The
are
-4 m -1 10
demonstrates namely smoke
value
and
of
that
which
the can
parameters
absorption be
used
of to
that
correlation
with
on
the
smoke
are
-3 pg m .
smoke both
times
obtained
Roof: units
are
flow
work wintertime
deter-
methods
Nuclepore
correlation
level
all
two a high
for
variability
of
concentration
b
absorption
(values excellent
This
and
limits.
smoke/mass roof
the
Previous
particle
that
mass
had The
sampler
than
quarter
for
matter.
two
the
case
particles.
these
the
one
the
z/3
Road:
The
b,
concentration.
Absorption The
smoke=0.83x(fine
the
about
a dichotomous
lie
relates In
smoke=mass
absorption
are
been
fine
1 shows
by
have
and
Fig.
defined
optical
particulate
relatively
results
However,
would
the
< 15 pm)
well
values filter.
than
made
(mass,
smoke
Nuclepore
total
present
is
the
closer
only
the
smoke.
cases
siderably
between
the
predict
are elemental the
determined carbon absorption
by
the
content coefficient
same of
the and
137
Fig.
3.
The
oarticle in
relationship
mass
this
used
way to
concentration data
the
importance
smoke
The
values
of
rooftop
in
the
to
refine
more
as
that
The
on
O-100
ug m
limited
, the
of
Nucleoore
of
which
there
above
suggest
ha/smoke
a rather lower figure -3 smoke . So further ug m
of
the
= 0.038
M,, - 0.10,
corr.
coeff.
0.89
Roof:
b,
= 0.021
Mn - 0.05,
corr.
coeff.
0.89
values
a (ba/Mn)
clearly
demonstrates
general
urban
both
ba and
aerosol. 15)
are
the
is
close
to
of the
emissions.
of by
the
m
road
-3
deal,
of
can
be
visibility the
range
Previous 2 -1 3 m g work
of work from
is
at data
necessary
The
and
2.1
about of
is
ratio
of
4.5
2 -1 m g 5-5.5
the
mass
is
not
as
good
are
.
aerosol
the
range
lines
Mn pg
roadside
Taking a value
engine
regression
units 2 -1 m g
3.9
that
Mn gives
diesel
and
atmosphere.
This for
10e4mm1
The
with
ba
b
3).
coefficient
Road:
of
(Fig.
absorption
smoke
tion
a great
that for 2 -1 5 m g .
:
the
relationship.
correlation
units
is
on atmospheric
with
with
ba and
filter.
absorption
ratio
O-30
coefficient
the
optical
gave
range
absorption
from
equations -3
(unpublished)
this
optical
smoke, of
regression
site
the
obtained
historical
assess
degradation.
oJr
between
average 2 -1 m g
darker
the for 2 -1 m g
than
(road-roof) the found
specific on
the that
absorpThis
roof. of
the
differences
traffic by
for
generated Japar
et
al.
(ref.
138 Aerosol
Composition
The
percentage
ranged
from
hydrocarbons salts.
extremely + NO,
17::
of
t
mass
dust, four add
lap
of
up
and
to
large
partly
total
because
because
on
the
0,
the
of
average
ash
and
to
average
be
formed
suggesting
in
roadside
of
Table
ash
2 are
non-volatile
ionic
during
that
re-entrained
fraction
listed
H removed
found
non-volatile
on
(7-48-A)
amount
aerosol
N and
The
roof.
variable
The
were
and
the
volatile
especially
heating
chromatography 22':
filters
includes
measured.
very
size.
the
fibre
species, after
a significant
particle to
100%
partly
was
glass figure
inorganic
ion
and
combustion
the
This
routinely
by road
collecting
contributions
of
not
the
on 50-L.
concentrations
analysed by
after was
probably
The
were
of
amounts ion
therefore
mass ash
collected
average
small
were
ions
of
an
with
original
precipitator
matter
with
ammonium
and
so;-
the
The
volatile 73:;
The
small
cl-
to
to
together
ammonium
the
of
24::
was not
21'j.
expected
fractions
combustion
are
over-
not
allowed
for. The
'non-volatile
Allowing
for
carbon'
ca.
15%
be
regarded
volatile/non-volatile carbon
is
is
that
the
consistent
that
organics
particles 2-3.
in
fraction
of
Fig.
Los
the
with
scattered
the
Abs.
coeff. =
suggests that 2 -1 and about 1 m g 2 -1 This latter m 9 .
the
elemental
not
of
more
of
than
elemental
18-27:: specific
the
Non-Vol.
the
non-carbonaceous
the
carbonaceous
+
the
total
carbon.
(ref.
16)
found
sub
2.1
14.9';
of
the
ratio
was
in
which
the
'black
the
This
.m
range carbon'
17).
absorption
coefficient
The line
points
of
are
the
rather
is
1.26
particles
in-
al.
(ref.
(Units:
aerosol
this
et
carbon.
C)
non-volatile carbon,
of
in
regression
17.'. the
'/3
carbon
the
averaged
matter,
Gray
surveys
for
an
the
carbon
non-volatile and
with
Since
example
various
ranged
5-252,
2:l. to
total/elemental
of
(Z
50% volatile
about
and
variation
0.7)
0.147
This
26.7b
carbon
percentage
the
limit is
results
the
from
within
studies,for
The
the
is
upper
carbon
for
total
(corr.
an
other
Angeles.
gives
4 presents
aerosol
Spec.
many
accounted
Novakov
ratio
as
elemental
with
ranged
species
carbon
to
dicates
fraction
inorganic
has
m
2
g
a specific
a specific
-1
)
absorption
absorption
of
of 15-16
figure is subject to considerable uncertainty. Although 2 -1 for elemental carbon have been quoted the majority figures as high as 15 m g 2 -1 basis the absorption coof authors favour a figure nearer 10 m g . On that -4 -1 efficient is given simply by ba (10 m ) = 0.1 x (Elemental Carbon pg m -3). Finally, Clayton Total for total
the
the
relationship
(ref.
2)
found
Carbon
=
0.42
range carbon
O-200 indicates
of
(smoke) + -3 smoke. pg m that
the
smoke
to
4.34 Taking elemental
carbon
(Units: elemental carbon
may
be
ug m
considered. -3
carbon concentration
Bailey
and
) to
be one is
Ca.
third 14% of
of
139
‘. 0
1-ig.
4.
The
age
of
the
smoke
B).
Their
on
of
This
carbon.
However
ponded
to
12 pg
was
s,moke.
14 71
? 4% of ug of
the
This
using
50 on
carbon.
figure,
as
(m2
of
the is
pg
the
findings
pg
value
smoke.
particulates
the
50
was
Standard
non-volatile
elemental
with that
this
coefficient
g-l)
with
percent
aerosol.
consistent
British
20
C %
absorption the
indicated
corresponding thus
in
is
correlation
is
specific
carbon
value.
elemental the
variation
non-volatile
Non -;‘d
of
smoke
Nuclepore
is
et
smoke.
at
our
carbon
is
(al.
(ref.
toGi
calibration
ug
filter
slightly
Edwards
corresponded
O.E.C.U. 42.5
Non-volatile
anticipated,
of
smoke
1-19 of
curve
The
and
elemental
carb-
roadside
site
of
about
17% or
about
24%
which
therefore
higher
than
the
a major
role
in
corres-
figures
of
for
carbon.
CONCLUSIONS Traffic-generated pollution.
carbonaceous They
>lmetric
mass
properties
result
carbon -indirect
marked
concentrations, (filter
However, properties
content methods
the of
also and
there
because of
local
but
reflectance
concentrations. optical
in
aerosols
aerosol monitoring
of
variations in
the
optical
is
common these
carbon
not
dependence
the
in
atmosphere.
urban
elemental provide
grav-
optical
and between
the
and
the
coefficient)
on
air
smoke
between
relationship
inter-relationships in
only
relationship absorption
a consistent
their and
play
the the
mass two
or valuable
black
140
REFERENCES 1. 2.
3.
a.
9. 10.
11.
12.
13.
14.
15.
16.
17.
British Standard 1747, Part 2, 1969, HMSO, London. D.L.R. Bailey and P. Clayton, The measurement of suspended particle and total carbon concentrations in the atmosphere using standard smoke shade methods, Atmos. Environment, 16 (1982), 2683-2690 D.J. Ball and R. Hume, The relative importance of vehicular and domestic emissions of dark smoke in Greater London in the mid-197Os, the significance of smoke shade measurements, and an explanation of the relationship of smoke shade to gravimetric measurements of particulate, Atmos. Environment, 11, (1977) 1065-1073. V.P.tI. llhelan, Smoke and Sulphur Dioxide pollution in Leeds, M.Phil. Thesis, University of Leeds, 1980. D.C. Siegla and G.W. Smith (Eds.), Particulate Carbon: Formation during combustion, Plenum Press, New York, 1981. G.T. Wolff and R.L. Klimisch (Eds.), Particulate Carbon: Atmospheric life cycle, Plenum Press, New York, 1982. H. Malissa, H. Puxbaum and T. Novakov (Eds.), Proc. of the 2nd Internat. Conf. on Carbonaceous Particles in the Atmosphere (1983). The Science of the Total Environment, Vol. 36, 1984. J.D. Edwards, J.A. Ogren, R.E. Ueiss and R.J. Charlson, Particulate air A comparison of British pollutants: 'smoke' with optical absorption coefficient and elemental carbon concentration, Atmos. Environment, 17 (1983) 2337-2341. A.G. Clarke, M.J. Willison and E.M. Zeki, A comparison of urban and rural aerosol composition using dichotomous samplers, Atmos. Environment, 18, (1984) 1767-1775. M.J. Willison, A.G. Clarke and E.M. Zeki, Seasonal variation in atmospheric aerosol concentration and composition at urban and rural sites in northern England, Atmos. Environment, 19 (1985) 1081-1089. A.G. Clarke and K.J. Morris, The relative contributions of scattering and absorption of light to visibility degradation by aerosols, in 6. Versino and H. Ott (Eds.), Physico-Chemical Behaviour of Atmospheric Pollutants, Proc. of the 2nd European Symposium, D. Reidel Pub. Co., Dordrecht, Holland, 1982, pp.280-286. C.I. Lin, M.B. Baker and R.J. Charlson, Absorption coefficient for atmosH method for measurement, Applied Optics, 12(1973) 1356pheric aerosol: 1363. R.K. Patterson, Automated Pregl-Dumas technique for determining total carbon, hydrogen and nitrogen in atmospheric aerosols, Anal. Chem, 45 (1973) 605-609. S.H. Cadle and P.J. Groblicki, An evaluation of methods for the determination of organic and elemental carbon in particulate samples in particulate carbon: Atmospheric Life Cycle, ref. 6 above, pp.89-108. S.M. Japar, A.C. Szkarlat and W.R. Pierson, The determination of the optical properties of airborne particulate emissions from diesel engines in Science of the Total Environment, ref. 7 above, pp.121-130. H.A. Gray, G.R. Cass, J.J. Huntzicker, E.K. Heyerdahl and J.A. Rau, Elemental and organic carbon particle concentrations: A long term prospective, in Science of the Total Environment, ref. 7 above, pp.l7-26. T. Novakm, Soot in the atmosphere, in Particulate Carbon: Atmosphere Life Cycle, ref. 6 above, pp.19-37.
Elsevier
AND
CHEMICAL
CLARKE
and
Department
of
B.V..
131-110 - Printed in The
Amsterdam
PROPERTIES
I.
131
59 (1987)
Enuironment,
Publishers
OPTICAL
A.G.
of the Total
Science
OF ROADSIDE
Netherlands
AEROSOLS
PAPAPANAYOTOU
Fuel
and
Energy,
Leeds
University,
Leeds,
LS2.9JT.
SUMMARY Roadside aerosols have been monitored by a variety of techniques. Optical reflectance of Whatman No.1 filters gave the British Standard smoke value. The optical absorption coefficient was measured by the integrating plate method after collection on Nuclepore filters. As expected there is a good correlation between optical absorption and smoke concentrations but a somewhat poorer correlation of these values with the mass concentration determined gravimetrically. Tc distinguish between local traffic emissions and the general urban background simultaneous monitoring was undertaken at a rooftop site away from the read. The specific absorption coefficient values were higher at the roadside than on the rooftop reflecting the higher proportion of carbonaceous material near to traffic. To assess the importance of the elemental and organic carbon content of the aerosol to the optical properties, two further measurements were made. The fraction of volatile matter in the aerosol was determined bv thermal desorotion and the carbon content of the non-volatile remainder was determined us-ing an elemental analyser. The fraction of volatile matter, which includes hydrocarbons and some inorganic species such as NH4N03. was found to be in the range 24-73X and to be slightly higher away from the road. The non-volatile carbon was found to be in the range 6-25:; by the road. The specific absorption increases with the fraction of non-volatile carbon.
INTRODUCTION It
is
well
known
relationship
to
particulate (based
total
mass
where
there
on
With
are
In
the
.3)
since ularly
the
similar
mass
coal
and
is to
lead
1 km from
004%9697/87/$03.50
much
77::
as
a factor
of
coal
are
darker
site
the
of
(ref.
i).
Ball
of
and
Hume,
Elsevier
the
of
carried
Publishers
London had
was
this
origin particA
the
correlation
of
at
the
Polytechnic There,
the
Hume
emissions,
out
B.V.
and
vehicles.
laboratory.
areas
particulate Ball
in
mass
in
between
engined
involving
authors'
Science
of
value. value
smoke the
Only
emissions
urban
the
2). equality
the
general diesel
cities,
(ref.
shade
airborne
underestimate
the
smoke
smoke
than
was of
the
a variable of
may
2-3 does
has
U.K.
l),
smoke
proportion
proportion
of
0 1987
of
lower
concentrations, the
of
ref.
determining
A much
a high that
atmosphere
valid
in
average
emissions there
concentration
smoke,traffic-generated role
on
measurement
mass
approximately
traffic.
traffic
analysis
than
in
smoke
calibration,
concentrations
that
where
as
Standard determined urban
1963
a significant
by
general
by
high
decline
found
British
the
remain
play
(ref.
less
original
concentration
contributed
total
the
measurements
matter
the
gravimetrically
matter.
value
two
that
the
smoke, in
the
Leeds
132 proportion
of
The elemental with
value
in
relation (see
absorption
Edwards
et
elemental
of
this
(Clarke
and
a major
have
work
side
the and
the
give
an
ed
the
be
obtained more
the
data
aerosol
is
been
obtained
has
particles
in
between was
value
the
the
atmos-
B.S.
smoke,
used
to
investigated
could
by
be
of of
the
local
variations
of
the
other
sources
but
very
fine
predict
in
the
aerosol. reported
aerosols
were
a minor
particles
of
optical
relative
the
made.
the
road-
matter these
of of
In
the
volatile
properties
on
Llm).
of by
Together
proportion
shown
0.1
made both
Some
effect
(s
been
been
main
the
concentrations
been
have the
been
only
have
measurements have
variations
of
roadside
mass
content
in
of have
measurements
Supplementary
from
although
coefficient
and
carbon
University
lo),
components
generated
paper,
the
Leeds
coefficients
presence
present
at 9 and
soluble
absorption the
the
levels
Freshly
the
level.
and
and
to
carbon,
(refs.
water
coefficient
rooftop
arising
of
and
smoke
of
also
of
correlation
the
scattering
11). on
suggesting
indication
emissions
on and
ref.
in
aerosol
aerosols
was
absorption at
previous
effect
reported
smoke,
studies
Morris,
scattering,
the
pollution
by
absorption
to
that
particulate
work
optical
5)
4).
An alternative,
amount
elemental
found
may
2). behaviour
The
ref. absorption
correlations
optical
7).
and
who
Ilhelan,
optical
(ref.
(ref.
6 and
(V.P.H. the
carbon.
characterised
on
good
emissions
refs.
8)
by
a considerable
coefficient (ref.
582
carbon) the
and
engine
atmospheric
emphasis
in
b,
in
al.
sub-Pm The
organic
describing
to
was
although
and
articles
optical
light
determined
coefficient
phere
data
smoke
primarily
parameter,
absorption
well
generated
carbon
(elemental
fundamental
the
is
(graphitic)
total
both
traffic
smoke
data
the
traffic
generat-
particles.
EXPERIMENTAL Measurements side
site
windm5 of
were
was m above
the
main
ground
routes
diesel-engined
5-102.
level
ca.
below.
representing The calibration
Most
samples
and
were
normal
given
in
is
to
50 m from air of
10
week
day
the
to
traffic
is
a high
some
main
roadfloor
lights
on
frequency
fraction parameters
one of
but
a re-
of
diesel
were
made
at
road.
velocities
are
duration
(8.30
hours
The
a first
cars,
overall
of
flow
through
petrol-engined The
vehicles.
1985.
in
There
addition
and
drawn
adjacent
centre.
measurements
media
concentration curve
in
October-December being
site
city
goods
30 m high
day-time, smoke
The
Simultaneous
sampling
period
samples
Leeds
of
is
shown
of
buses
vehicles
various
level.
out
the
curb,
passenger small
The
during
the
proportion
latively
rooftop
made
5 m from
indicated
in
a.m.-6.30
Table
1
p.m.),
conditions.
was
obtained
from
the
British
Standard
the
filter (ref.
reflectance 1).
Samples
using for
the the
133 absorbance
measurements
particle
mass
4503
on
concentrations
microbalance.
the
lowest
ed.
However,
concentration
A back-up
using the
two
filters
methods El,
trations
was
are
TABLE
weights of
when the
less
mass
times
in
Standard
smoke
particles
Mm was rate.
The
0.97,
were
made
agreement
N=65,
at
collect-
therefore
between
regression
line
mass
concen-
The
and
Lin,
absorbance Baker
duction
Charlson
light
particles age.
measurements
and
of
inated
by
tector.
on
Morris,
ref.
by
trap be an 80
the
used
This
the
Rate
involves
the
the
disk
at
24 80
by
than
filter
been
method of
caused
the
and
the
re-
cover-
light
given
of
the
monolayer
scattered
the
have
plate
measurement
less
forward
between
apparatus
2
filter
filter of
e/min.
1.5
integrating
a Nuclepore
intensity
opal
is of since
carbon
of not
content
elemental
the
filter
is
elim-
light
elsewhere
only
coarser
deposits
of
particulate on
the
combustion
since
particles,
the
preventing particles
on
were of
de(Clarke
tube
filter
the
573).
inside
(2
Use
surface
ug
been in
un-
re-
attempted
the
Impaction
This
a
filters
has
melts
using
technique
fibre
collected.
Model
made
this
matter glass
combustion. are
(Bendix particles
aerosols Application
collection in
straightforward
the
roadside
amounts
Although
precipitator and
of analyser.
large
form.
insertion
electrostatic g/min.
an
rather
compact
this some
using
of
the
author's
C.N.H.
requires
12)
Flow
11).
240C
in
followed (ref.
the
of
fortunately comnlended)
surface of
of
of
Measurements Elmer
12).
made
through
the
presence
Details
Pet-kin
(ref.
dependence the
were
transmission
collected Angular
Media
Whatman No.1, cellulose, 25 m clamps Nuclepore, 25 mm, 0.2 pm pore size Whatman, 37 nun, membrane filter, 1 pm pore size Whatman, 55 mm, glass fibre GF/F
Volatiles
ca.
of
off
methods.
Optical absorbance mass concentration Mass concentration
of
a Sartorius drops
Nuclepore-derived
Filter
British
not
with
the
error.
Measurement
may
obtain
1
E.iperimental
and
taken
ug
coefficient the
to
measurements
50
flow
that
used
were these
than
higher
confidence
seriously
also
concentration
(correlation
giving
not
Filter accuracy
ten
good
+ 4.84)
were
the
of at
filters
M,.
levels
measurement
membrane
M,,,=0.97
Nuclepore
process methods
was
therefore
has
a flow
of
removabl'a
and canmade
rate
of
134 aluminium the
cylinders
of
cylinders, in
the
weights
However,
sample
in
of
14).
remove
all
carbon
values
only
iculate
one
be
determined.
that
for
hears
of
this
reason
the
results
is
has
are
upper
(e.g.
does
not The
limits
reported
and
shown
as organic. as
a
elemental
techniques
regarded
total the
There
separating
identify
be
aerosol
than
devolatilisation
techniques
therefore
out
the
heating
analysis.
of
various
by
off
dried of
rather
removed
before
methods
and
N content
carbon
was
temperature
other
should
elemental carbon
24
low
electrostatic
material,
and
the
roof
was
used
before
s/min.)
and
The
then
species.
0f cl-,
rdo3-, so4
to
as
presented
simply
flow
flow
the
the
true
.non-
rates
ments
were
used
imply
particles
such
the
fractions
the
mass
NH4C1,
mass
there as
of
to will
volatile
were
be
used
roadside and
data
obtain
hydrocarbons soluble the
fibre
the
smoke
sampling
matter
samples
matter
collected
expected
that
& Nuclepore
efficiency In
dust.
is
filter
the
discussion
have
not
concentrations
itimasses
are
high measure
the
combined of
some
coarse of
been
hours
since the
filter for
24 and
and
glass
absolute
re-
for
of
It
carbonaceous to
before oven
water
particulate
for
175'C
amount
and
a greater
two at
the
monitored.
those
the
with
chromatography.
the
precipitator
assess
ion
of
roadside
the by
a vacuum
part-
the
preheated
a desicator in
of
leached
samples
accurately
as
includes
To
filters by
in
volatiles
NH4N03).
the
re-entrained
concentration
as
fractions
not
compared
that
lost
both
sampled were
175'C
amounts
rate
ranges
dried
at
at
flow
filters
was
heating
precipitator
as
rates
size
small
taken
same
clean
filter
after
remaining, 2- determined
from
The
matter
were The
particle
exposed
(e.g.
material
samples
the
loss The
organic
Results
that
the
producing
filters.
comparable.
weight
obtained.
inorganic
fibre
so be
weighing
filter
glass
should
weighing.
precipitator
additional using
(80
approaches
the
also
scraped
carbon'.
Having
was
can in
was boats
H and
comparisons
carbon
sample C,
various
the
deposit
the
for
the
that
and
platinum
was
175'C
The
gives
organic
in
obtained
carbon
volatile
interest
at
likely
the
normal
volatile
detailed
is
of
elemental
main the
oven
as
It
the
combustion
variability
carbon
ref.
of
a vacuum
deal
organic
the
bulk
diameter.
Analysis after
since the
great
to
a desicator.
ash
carbon,
mm internal
transferred
overnight and
37
results with
volatiles
and
carbon.
RESULTS Table British The dicated
2 summarises Standard roadside by
the
the
average
values
found
in
this
study.
Smoke smoke rooftop
values values
were
more
(averages
than 45
double and
the
18 ug
m
urban background -3 respectively).
inThe
135 TABLE
2
Average
Values
of
the
Parameters
Measured
-Parameter
Units
E S.
Smoke
u5t.m
Mass
Concentration
i-1g.m -3
Roadside
--
Absorption Coefficient
10-4m-1
Specific Coefficient
Abs.
Volatile
Fraction
Non-Vol. Fraction
Ionic
Non-Vol. Fraction
Carbon
Ash
mg2 -1
will
It
is
not
sum
to
100':.
relationship The
to
with
regression
be
lines
33
37.4
34
2.3
0.7
34
3.9
2.1
34
50
43
36
/J
17
22
27
that
the
gravimetrically
17
27
21
27
four
fractions
determined
t
2.41,
Corr.
Coeff.
0.86
Roof:
Smoke
= 0.70
M,
-
3.67,
Corr.
Coeff.
0.93
The
relationship matter
is
in
illustrated
the
table
in
Fig.
are M,
particulate
listed
mass
= 0.67
of
of Data Pairs
18.0
Smoke
1.
Ho.
73.2
Road:
Fig.
Value
,':
expected
the
Roof
45.5
c//L, rl,J
Fraction
N B.
-3
Value
of determined
British
Standard using
Nuclepore
smoke
with filters.
the
mass
concentration
1.
136
Fig.
2.
The
British
relationship
Standard In
both
mined
from
the
used
for collects
top
site
suspended
use
of
0.92)
which
aerosol.
roof
coefficient
between
road to
fact
The
values
the at
and
Coefficient average
greater
mass,
< 2.5
(corr.
con-
rate
method
sampling on
Pm)
been
method
the
same
gave
in
the
is coeffs.
points
roof-
smoke=0.55x
(ref.
10).
Our
significantly 0.86
composition
lie
near
2.3
and
0.7
as
shown
in
coefficient -4 -1 x 10 ni Fig.
2.
by
the
road
was
as of
the
respectively). The
three
The
regression
lines
less compared
the
line
to
roadside
along
ba
= 0.055
(smoke)
- 0.141,
corr.
coeff.
0.99
ba
= 0.047
(smoke)
- 0.160,
corr.
coeff.
0.97
of
ba
clearly
physical
property
aerosol.
The
are
-4 m -1 10
demonstrates namely smoke
value
and
of
that
which
the can
parameters
absorption be
used
of to
that
correlation
with
on
the
smoke
are
-3 pg m .
smoke both
times
obtained
Roof: units
are
flow
work wintertime
deter-
methods
Nuclepore
correlation
level
all
two a high
for
variability
of
concentration
b
absorption
(values excellent
This
and
limits.
smoke/mass roof
the
Previous
particle
that
mass
had The
sampler
than
quarter
for
matter.
two
the
case
particles.
these
the
one
the
z/3
Road:
The
b,
concentration.
Absorption The
smoke=0.83x(fine
the
about
a dichotomous
lie
relates In
smoke=mass
absorption
are
been
fine
1 shows
by
have
and
Fig.
defined
optical
particulate
relatively
results
However,
would
the
< 15 pm)
well
values filter.
than
made
(mass,
smoke
Nuclepore
total
present
is
the
closer
only
the
smoke.
cases
siderably
between
the
predict
are elemental the
determined carbon absorption
by
the
content coefficient
same of
the and
137
Fig.
3.
The
oarticle in
relationship
mass
this
used
way to
concentration data
the
importance
smoke
The
values
of
rooftop
in
the
to
refine
more
as
that
The
on
O-100
ug m
limited
, the
of
Nucleoore
of
which
there
above
suggest
ha/smoke
a rather lower figure -3 smoke . So further ug m
of
the
= 0.038
M,, - 0.10,
corr.
coeff.
0.89
Roof:
b,
= 0.021
Mn - 0.05,
corr.
coeff.
0.89
values
a (ba/Mn)
clearly
demonstrates
general
urban
both
ba and
aerosol. 15)
are
the
is
close
to
of the
emissions.
of by
the
m
road
-3
deal,
of
can
be
visibility the
range
Previous 2 -1 3 m g work
of work from
is
at data
necessary
The
and
2.1
about of
is
ratio
of
4.5
2 -1 m g 5-5.5
the
mass
is
not
as
good
are
.
aerosol
the
range
lines
Mn pg
roadside
Taking a value
engine
regression
units 2 -1 m g
3.9
that
Mn gives
diesel
and
atmosphere.
This for
10e4mm1
The
with
ba
b
3).
coefficient
Road:
of
(Fig.
absorption
smoke
tion
a great
that for 2 -1 5 m g .
:
the
relationship.
correlation
units
is
on atmospheric
with
with
ba and
filter.
absorption
ratio
O-30
coefficient
the
optical
gave
range
absorption
from
equations -3
(unpublished)
this
optical
smoke, of
regression
site
the
obtained
historical
assess
degradation.
oJr
between
average 2 -1 m g
darker
the for 2 -1 m g
than
(road-roof) the found
specific on
the that
absorpThis
roof. of
the
differences
traffic by
for
generated Japar
et
al.
(ref.
138 Aerosol
Composition
The
percentage
ranged
from
hydrocarbons salts.
extremely + NO,
17::
of
t
mass
dust, four add
lap
of
up
and
to
large
partly
total
because
because
on
the
0,
the
of
average
ash
and
to
average
be
formed
suggesting
in
roadside
of
Table
ash
2 are
non-volatile
ionic
during
that
re-entrained
fraction
listed
H removed
found
non-volatile
on
(7-48-A)
amount
aerosol
N and
The
roof.
variable
The
were
and
the
volatile
especially
heating
chromatography 22':
filters
includes
measured.
very
size.
the
fibre
species, after
a significant
particle to
100%
partly
was
glass figure
inorganic
ion
and
combustion
the
This
routinely
by road
collecting
contributions
of
not
the
on 50-L.
concentrations
analysed by
after was
probably
The
were
of
amounts ion
therefore
mass ash
collected
average
small
were
ions
of
an
with
original
precipitator
matter
with
ammonium
and
so;-
the
The
volatile 73:;
The
small
cl-
to
to
together
ammonium
the
of
24::
was not
21'j.
expected
fractions
combustion
are
over-
not
allowed
for. The
'non-volatile
Allowing
for
carbon'
ca.
15%
be
regarded
volatile/non-volatile carbon
is
is
that
the
consistent
that
organics
particles 2-3.
in
fraction
of
Fig.
Los
the
with
scattered
the
Abs.
coeff. =
suggests that 2 -1 and about 1 m g 2 -1 This latter m 9 .
the
elemental
not
of
more
of
than
elemental
18-27:: specific
the
Non-Vol.
the
non-carbonaceous
the
carbonaceous
+
the
total
carbon.
(ref.
16)
found
sub
2.1
14.9';
of
the
ratio
was
in
which
the
'black
the
This
.m
range carbon'
17).
absorption
coefficient
The line
points
of
are
the
rather
is
1.26
particles
in-
al.
(ref.
(Units:
aerosol
this
et
carbon.
C)
non-volatile carbon,
of
in
regression
17.'. the
'/3
carbon
the
averaged
matter,
Gray
surveys
for
an
the
carbon
non-volatile and
with
Since
example
various
ranged
5-252,
2:l. to
total/elemental
of
(Z
50% volatile
about
and
variation
0.7)
0.147
This
26.7b
carbon
percentage
the
limit is
results
the
from
within
studies,for
The
the
is
upper
carbon
for
total
(corr.
an
other
Angeles.
gives
4 presents
aerosol
Spec.
many
accounted
Novakov
ratio
as
elemental
with
ranged
species
carbon
to
dicates
fraction
inorganic
has
m
2
g
a specific
a specific
-1
)
absorption
absorption
of
of 15-16
figure is subject to considerable uncertainty. Although 2 -1 for elemental carbon have been quoted the majority figures as high as 15 m g 2 -1 basis the absorption coof authors favour a figure nearer 10 m g . On that -4 -1 efficient is given simply by ba (10 m ) = 0.1 x (Elemental Carbon pg m -3). Finally, Clayton Total for total
the
the
relationship
(ref.
2)
found
Carbon
=
0.42
range carbon
O-200 indicates
of
(smoke) + -3 smoke. pg m that
the
smoke
to
4.34 Taking elemental
carbon
(Units: elemental carbon
may
be
ug m
considered. -3
carbon concentration
Bailey
and
) to
be one is
Ca.
third 14% of
of
139
‘. 0
1-ig.
4.
The
age
of
the
smoke
B).
Their
on
of
This
carbon.
However
ponded
to
12 pg
was
s,moke.
14 71
? 4% of ug of
the
This
using
50 on
carbon.
figure,
as
(m2
of
the is
pg
the
findings
pg
value
smoke.
particulates
the
50
was
Standard
non-volatile
elemental
with that
this
coefficient
g-l)
with
percent
aerosol.
consistent
British
20
C %
absorption the
indicated
corresponding thus
in
is
correlation
is
specific
carbon
value.
elemental the
variation
non-volatile
Non -;‘d
of
smoke
Nuclepore
is
et
smoke.
at
our
carbon
is
(al.
(ref.
toGi
calibration
ug
filter
slightly
Edwards
corresponded
O.E.C.U. 42.5
Non-volatile
anticipated,
of
smoke
1-19 of
curve
The
and
elemental
carb-
roadside
site
of
about
17% or
about
24%
which
therefore
higher
than
the
a major
role
in
corres-
figures
of
for
carbon.
CONCLUSIONS Traffic-generated pollution.
carbonaceous They
>lmetric
mass
properties
result
carbon -indirect
marked
concentrations, (filter
However, properties
content methods
the of
also and
there
because of
local
but
reflectance
concentrations. optical
in
aerosols
aerosol monitoring
of
variations in
the
optical
is
common these
carbon
not
dependence
the
in
atmosphere.
urban
elemental provide
grav-
optical
and between
the
and
the
coefficient)
on
air
smoke
between
relationship
inter-relationships in
only
relationship absorption
a consistent
their and
play
the the
mass two
or valuable
black
140
REFERENCES 1. 2.
3.
a.
9. 10.
11.
12.
13.
14.
15.
16.
17.
British Standard 1747, Part 2, 1969, HMSO, London. D.L.R. Bailey and P. Clayton, The measurement of suspended particle and total carbon concentrations in the atmosphere using standard smoke shade methods, Atmos. Environment, 16 (1982), 2683-2690 D.J. Ball and R. Hume, The relative importance of vehicular and domestic emissions of dark smoke in Greater London in the mid-197Os, the significance of smoke shade measurements, and an explanation of the relationship of smoke shade to gravimetric measurements of particulate, Atmos. Environment, 11, (1977) 1065-1073. V.P.tI. llhelan, Smoke and Sulphur Dioxide pollution in Leeds, M.Phil. Thesis, University of Leeds, 1980. D.C. Siegla and G.W. Smith (Eds.), Particulate Carbon: Formation during combustion, Plenum Press, New York, 1981. G.T. Wolff and R.L. Klimisch (Eds.), Particulate Carbon: Atmospheric life cycle, Plenum Press, New York, 1982. H. Malissa, H. Puxbaum and T. Novakov (Eds.), Proc. of the 2nd Internat. Conf. on Carbonaceous Particles in the Atmosphere (1983). The Science of the Total Environment, Vol. 36, 1984. J.D. Edwards, J.A. Ogren, R.E. Ueiss and R.J. Charlson, Particulate air A comparison of British pollutants: 'smoke' with optical absorption coefficient and elemental carbon concentration, Atmos. Environment, 17 (1983) 2337-2341. A.G. Clarke, M.J. Willison and E.M. Zeki, A comparison of urban and rural aerosol composition using dichotomous samplers, Atmos. Environment, 18, (1984) 1767-1775. M.J. Willison, A.G. Clarke and E.M. Zeki, Seasonal variation in atmospheric aerosol concentration and composition at urban and rural sites in northern England, Atmos. Environment, 19 (1985) 1081-1089. A.G. Clarke and K.J. Morris, The relative contributions of scattering and absorption of light to visibility degradation by aerosols, in 6. Versino and H. Ott (Eds.), Physico-Chemical Behaviour of Atmospheric Pollutants, Proc. of the 2nd European Symposium, D. Reidel Pub. Co., Dordrecht, Holland, 1982, pp.280-286. C.I. Lin, M.B. Baker and R.J. Charlson, Absorption coefficient for atmosH method for measurement, Applied Optics, 12(1973) 1356pheric aerosol: 1363. R.K. Patterson, Automated Pregl-Dumas technique for determining total carbon, hydrogen and nitrogen in atmospheric aerosols, Anal. Chem, 45 (1973) 605-609. S.H. Cadle and P.J. Groblicki, An evaluation of methods for the determination of organic and elemental carbon in particulate samples in particulate carbon: Atmospheric Life Cycle, ref. 6 above, pp.89-108. S.M. Japar, A.C. Szkarlat and W.R. Pierson, The determination of the optical properties of airborne particulate emissions from diesel engines in Science of the Total Environment, ref. 7 above, pp.121-130. H.A. Gray, G.R. Cass, J.J. Huntzicker, E.K. Heyerdahl and J.A. Rau, Elemental and organic carbon particle concentrations: A long term prospective, in Science of the Total Environment, ref. 7 above, pp.l7-26. T. Novakm, Soot in the atmosphere, in Particulate Carbon: Atmosphere Life Cycle, ref. 6 above, pp.19-37.