Title: Ground-based Measurements
1Ground-based Measurements
- Measurements
- Retrieving the Desired Information
- Comparison Between Instruments
- Satellite Validation
- Toward Model-Measurement Comparison
Prepared by Dr. Stella M L Melo University of
Toronto
Part of the material presented here was provided
by Prof. K. Strong
2Points
- Understanding what is measured
- Extracting the desired information from the
measurement - Comparing measurements made using different
techniques - Measurements and models
3Measurement
- Remote sensing/sounding
- a means of obtaining information about an object
or medium without coming into physical contact
with it. - This generally involves the measurement of EM
radiation that has interacted with the object or
medium of interest.
4Interaction of Radiation with Gases
- Ionization dissociation (UV)
- Electronic transition (UV- visible)
- Vibrational transitions (infrared)
- Rotational transitions
5Measurement
- Remote sensing/sounding techniques can be
classified by the type of measurement and the
spectral region. - ACTIVE vs. PASSIVE
- IMAGING vs. NON-IMAGING vs.
- WAVELENGTH OF RADIATION MEASURED
6ACTIVE
RADAR
(m-WAVE)
FABRY-
FOURIER
GRATING
PEROT
TRANSFORM
(UV/VIS/IR)
(VIS/IR)
(VIS/IR)
7Measurement
- Passive Systems
- These generally measure the extinction, emission,
or scattering of radiation in order to retrieve
atmospheric properties.
- Radiometers isolate bands of natural radiation
using some form of spectral filter - Spectrometers disperse natural radiation into
its constituent wavelengths over a finite
spectral range or use interference effects to
obtain spectral information - Monochromatic LASER Techniques - LASER is used
in a passive mode in a heterodyne system, serving
as a local oscillator
8Measurement
- Active Techniques
- (1)- radio (microwave) spectrum ? RADAR (RAdio
Detection And Ranging) - (2)-visible and infrared spectrum
- LASER (Light Amplification by Stimulated Emission
of Radiation) - LIDAR (LIght Detection And Ranging)
9Gas Absorption/Emission Spectroscopy
- Absorption and emission spectra provide a means
of identifying and measuring the composition and
temperature of the atmosphere.
http//ess.geology.ufl.edu/ess/notes/050-Energy_Bu
dget/absorbspec.jpeg
10Gas Absorption/Emission Spectroscopy
11Gas Absorption/Emission Spectroscopy
Four processes will change the intensity of the
EM radiation as it passes through the volume A
absorption from the beam (depletion term) B
emission by the material (source term) C
scattering out of the beam (depletion term) D
scattering into the beam (source term)
12What is measured
Passive remote sounding instruments are used to
observe extinction, emission, and scattering of
natural radiation.
Scattering
Extinction
Emission
13Measurements Techniques
- DOAS
- Retrieving vertical distribution of constituents
from ground-based measurements - Temperature form Airglow and from Lidar
14Ground based Measurements DOAS
- Differential Optical Absorption Spectroscopy
DOAS - a method to determine concentrations of trace
gases by measuring their specific narrow band
absorption structures in the UV and visible
spectral region Platt and Perner, 1983 Platt,
1994.
15DOAS
- Differential absorption cross-sections of some
trace gases absorbing in the UV/vis wavelength
region. - On the right axis the detection limits of the
trace gases is listed together with the typical
light path lengths used to measure them.
16DOAS
Varies slowly with l
17DOAS NO3
- Example of NO3 analysis
- Daytime reference and night time spectra to be
analyzed - The division of the two spectra with a low-pass
filter - The fit of NO3 to the OD spectrum, d) Residual
- e) and f) NO3 and H2O cross-section
From Allan et al., JGR 105, 2000
18Viewing Geometry
- Direct sun
- Zenith sky
- Bright-sky (less commonly used?)
Zenith Sky
Direct Sun
19Viewing Geometry
- Direct Sun
- Longer path through the troposphere (than zenith)
- Air mass factor calculation normally requires
only geometric considerations - Clear sky conditions are required
- Zenith Sky
- Longer path through the stratosphere
- Possible to measure absorption at SZA greater
than 90 - Any weather conditions
- Air mass calculation involves complex scattering
geometry - Bright-Sky
- Instrument points towards the brightest part of
the sky - Increased sensitivity to aerosol scattering
20Zenith sky configuration
- Particularly sensitive to stratospheric absorbers
- For the analysis of DOAS measurements using
direct or scattered solar radiation traversing
the atmosphere, the so-called air mass factor
concept has been developed (see e.g. Noxon et al.
1979, Solomon et al. 1987b). - Since the measured slant column density (SCD),
the integrated trace gas concentration along the
light path, strongly depends on the solar zenith
angle (SZA), it is advantageous to convert the
SCD into a vertical column density (VCD), the
vertically integrated trace gas concentration. - This conversion is usually performed by dividing
the SCD by the air-mass factor (AMF)
- VCD SCD(SZA) / AMF(SZA)
(apparent SCD)
21DOAS NO3
Figure 3. Examples of the variation in the
vertical column density of NO3 obtained from
zenith sky measurements during field campaigns
carried out at Weybourne, Mace Head, Tenerife,
Cape Grim and Norway.
From Allan et al., JGR 107, 2002
22DOAS NO3
Figure 6. Examples of profile retrieval from NO3
vertical column density measurements made on 3
February 1999 (triangles) and 15 February 1999
(circles) at Cape Grim, Tasmania.
From Allan et al., JGR 107, 2002
23U of T spectrometer Zenith Sky
24O3 DOAS fit
By Elham Farahani
25Ozone Eureka 1999
Fig. 1. Ozone vertical column densities measured
with the University of Toronto UV-visible
spectrometer, compared with data from sondes, a
Brewer spectrophotometer operated by the
Meteorological Service of Canada, and the TOMS
satellite instrument.
Melo et al., ASR, 2004
26NO2 DOAS fit
By Elham Farahani
27NO2 Vertical column
Fig. 2. NO2 vertical column densities at SZA90
observed with the UV-visible spectrometer. Values
were obtained assuming a reference column density
of 1.46x1016 molec.cm-2.
Melo et al., ASR, 2004
28NO2 Vertical distribution
NO2 slant column (x1017 molec cm-2)
(K. E. Preston et al., J. Geophys. Res. 102,
19089, 1997)
29Retrieval or inversion theory
- The direct or forward problem
- - A detector measures a signal S f(T) which is
generated by the interaction of radiation with
the target (atmosphere, clouds, etc.). - ? given properties of the target, calculate
signal - The inverse problem
- Want to determine properties of the target,
given by the inverse function T f-1(S). - ? given signal, calculate properties of the target
30Solving the inverse problem
- Solving the inverse problem is complicated by a
number of difficulties - (1) Non-uniqueness of the solution
- several unknown parameters, which can be combined
in different ways to generate the same observed
signal. i.e., have several solutions T1 f-1(S),
T2 f-1(S), etc. - (2) Discreteness of the measurements when the
measured quantity is a smoothly varying function.
e.g., T is a function of height z, while S is
measured at discrete levels over some range of
heights, so where K(z) is called a kernel
function or a weighting function. - (3) Instability of the solution due to errors in
the observations S. e.g., If ? is the error on S,
then where ? can produce a large change in the
retrieval of T(z).
31NO2 Vertical distribution
- The inversion problem consist of expressing the
unknown profile x in terms of the observations y
y measurements - SCD F forward model b
model parameter ey measurements error
yF(x,b)ey
Direct inversion? Well, the problem is
under-constrained
There is no unique solution choose the
optimal solution
32NO2 Vertical distribution
- For the purpose of retrieval, the inverse
problem can be reformulated in a discrete form
(Rodgers, 1976)
yKx where Kdy/dx
The rows of the K matrix are know as weighting
functions and each one corresponds to a different
measurement.
- Rodgers (1976) reviews a number of different
methods - Sequential estimation was chosen for this study
- Solving the optimal estimation equation
sequentially.
33NO2 Vertical distribution
- Vertical profile can be retrieved using optimal
estimation sequentially Rogers, 1990 - minimizes the difference between measured and
calculated slant column values as a function of
SZA to determine the optimum solution profile for
each set of twilight spectra. - is based on sequentially combining a set of
independent measurements by taking a weighted
average, using the measurement errors as weights.
- does not require iterations
- includes a formal treatment of errors.
- Vertical resolution 5 to 7 km from 10 to 35 km
altitude.
34Retrieval
- Optimal estimation
- Combining two independent measurements, x1 and
x2, by taking the average, using the inverse of
the error covariances, S1 and S2, as weight
Covariance matrix of x
- Those equations can then be used to invert
slant column measurements
35Retrieval
xK-1y The measurement error inverse covariance
S-1e can be mapped into profile space using the K
matrix KTS-1eK. x0 a priori with error
covariance Sx
Covariance of x
Simplifying
Can be solved sequentially
36Retrieval
- The measurements are treated as m scalars, yi,
with corresponding standard deviation si. - The a priori, x0, is the first guess of the
vertical profile - It is sequentially updated or improved using one
weight function Ki and one measurement yi at a
time - The error covariance S is retrieved
simultaneously with the vertical profile
37Does it works?
- CMAM vertical profiles of NO2 concentration for
Vanscoy for a set of SZA range during both
twilights are used to generate SCD as a function
of SZA (Chris McLinden). - Those SCD are used into a retrieval code to
retrieve back the NO2 vertical distribution at
sunrise and sunset (SZA90) - Both the forward model and the box model employed
in the retrieval are independent from either CMAM
or Chris McLinden models. - The a priori used in the retrieval is also
independent of CMAM.
38Testing NO2 retrieval
39Averaging Kernels
40Information content
- Smoothing CMAM using Rodgers aproach (Rodgers and
Connar, JGR 108, Vol D3, 4116, 2003) assume CMAM
is the true (Xh), the smoothed profile (Xs)
will be given by - XsXa A(Xh Xa)
- Xa represents the a priori adopted in the
retrieval and A represents the Averaging Kernels.
41Testing NO2 retrieval
42Adding Tropospheric NO2
Zenith viewing geometry low sensitivity to
troposphere
43Using measurements
Fig. 4. NO2 a priori, measured, and retrieved
absolute slant column densities for March 31,
1999 (day 90) measured at Eureka. Values were
obtained assuming RCD1.46x1016 molec.cm-2.
Melo et al., ASR, 2004
44Using real measurements
Eureka 1999
Fig. 5. Left plot retrieved NO2 profiles for
SZA90 on March 31st, 1999 (day 90) compared
with the initial profile. Right plot error in
the a priori and retrieved profiles. Values were
obtained assuming RCD 1.46x1016 molec.cm-2.
Melo et al., ASR, 2004
45NO2 and O3 Eureka 1999
Fig. 7. O3 partial pressure measured using a
sonde launched from Eureka at 2327 UT on March
31, 1999 (day 90).
NO2 Vertical distribution
46NO2 from different platforms
Figure 1. The NO2 slant columns measured with the
ground-based UV-visible spectrometer on August
24, 1998 (MANTRA) and the fitted values. The
symbols represent measured values while the lines
represent retrieved values. Lower plot the
percent difference ((measured-fitted)/measured),
sunrise (diamonds) and sunset (squares).
Melo et al., A-O, Submitted
47MANTRA Balloon Campaign
- MANTRA is conducted at Vanscoy, Saskatchewan
(52N, 107W) - - August 24, 1998,
- - August 29, 2000,
- - September 3, 2002,
- - NEXT August 2004
- Instruments of interest here balloon-based SPS,
SAOZ, and DU-FTS, the ground-based UT
Spectrometer and the sondes. - In this work we report on vertical profiles of T,
O3, NO2, N2O, CH4, and HCl concentrations .
48MANTRA Scientific Objectives
- To measure vertical profiles of the key
stratospheric gases that control the mid-latitude
ozone budget. - To combine these measurements with historical
data to quantify changes in the chemical balance
of the stratosphere, with a focus on nitrogen
compounds. - To compare multiple measurements of the same
trace gases made by different instruments. - To use the measurements for validation and
ground-truthing of Odin, ENVISAT, and SCISAT-1.
http//www.atmosp.physics.utoronto.ca/MANTRA
49MANTRA 1998
50NO2 - Comparing with models
- What kind of models?
- CTM - MEZON (Model for Evaluating oZONe Trends)
global chemistry-transport model. - horizontal resolution of 4 in latitude and 5 in
longitude - Vertical the model spans the atmosphere from the
ground to 1 hPa - driven by wind and temperature fields provided by
the UKMO - initial conditions for the trace-gas
concentrations have been taken from the UARS - lightning source of NOx is prescribed
- Rozanov et al. (1999) and Egorova et al. (2001,
2003) - GCM CMAM Canadian Middle Atmosphere Model
(CMAM) - upward extension of the Canadian Centre for
Climate Modeling and Analysis (CCCma) spectral
General Circulation Model (GCM) up to 0.0006hPa
(roughly 100 km altitude).
51NO2 diurnal variation - CMAM
52NO2 MANTRA MEZON (CTM)
53NO2 - Comparing with GCM
- NSEP/NCAR (1970-2001), UKMO (1993-2002) and
CMAM (24 years) long-term means of zonal wind
velocity over Vanscoy. (Wunch et al, A-O in press)
54NO2 MANTRA - CMAM
55NO2 - Comparing with CMAM
MANTRA Mid-latitude summer time
56NO2 - Comparing with CMAM
MANTRA Mid-latitude summer time
57MANTRA CMAM
1998 Campaign
58Reaction pathway between the principal NOy
constituents
Gao et al, GRL, 1999.
59Nitrogen Partitioning MANTRA - CMAM
- Dynamics establishes compact correlations -
Chemistry determines their shape