In atmospheric chemistry, differential optical absorption spectroscopy (DOAS) is used to measure concentrations of trace gases. When combined with basic optical spectrometers such as prisms or diffraction gratings and automated, ground-based observation platforms, it presents a cheap and powerful means for the measurement of trace gas species such as ozone and nitrogen dioxide. Typical setups allow for detection limits corresponding to optical depths of 0.0001 along lightpaths of up to typically 15 km and thus allow for the detection also of weak absorbers, such as water vapour, Nitrous acid, Formaldehyde, Tetraoxygen, Iodine oxide, Bromine oxide and Chlorine oxide.
DOAS instruments are often divided into two main groups: passive and active ones. The active DOAS system such as longpath(LP)-systems and cavity-enhanced(CE) DOAS systems have their own light-source, whereas passive ones use the sun as their light source, e.g. MAX(Multi-axial)-DOAS. Also the moon can be used for night-time DOAS measurements, but here usually direct light measurements need to be done instead of scattered light measurements as it is the case for passive DOAS systems such as the MAX-DOAS.
The change in intensity of a beam of radiation as it travels through a medium that is not emitting is given by Beers law:
I=I0\exp\left(\sumi\int\rhoi\betaids\right)
where I is the intensity of the radiation,
\rho
\beta
\sigma=\int\rhods
The new, considerably simplified equation now looks like this:
I=I0\exp\left(\sumi\betai\sigmai\right)=I0\prodi
| \betai\sigmai | |
| e |
If that was all there was to it, given any spectrum with sufficient resolution and spectral features, all the species could be solved for by simple algebraic inversion. Active DOAS variants can use the spectrum of the lightsource itself as reference. Unfortunately for passive measurements, where we are measuring from the bottom of the atmosphere and not the top, there is no way to determine the initial intensity, I0. Rather, what is done is to take the ratio of two measurements with different paths through the atmosphere and so determine the difference in optical depth between the two columns (Alternative a solar atlas can be employed, but this introduces another important error source to the fitting process, the instrument function itself. If the reference spectrum itself is also recorded with the same setup, these effects will eventually cancel out):
\delta=ln\left(
| I1 | |
| I2 |
\right)=\sumi\betai\left(\sigmai2-\sigmai1\right) =\sumi\betai\Delta\sigmai
A significant component of a measured spectrum is often given by scattering and continuum components that have a smooth variation with respect to wavelength. Since these don't supply much information, the spectrum can be divided into two parts:
I=I0\exp\left[\sumi\left
| * | |
| (\beta | |
| i |
+\alphai\right)\sigmai\right]
where
\alpha
\beta*
\deltad+\deltac=ln\left(
| I1d | |
| I2d |
\right) +ln\left(
| I1c | |
| I2c |
\right)=\sum\left
| * | |
| (\beta | |
| i |
+\alphai\right) \left(\sigmai2-\sigmai1\right) =\sumi
| * | |
| \beta | |
| i |
\left(\sigmai2-\sigmai1\right) +\sumi\alphai\left(\sigmai2-\sigmai1\right)
where we call
\deltad
\deltad(λ)=\sumi
| *(λ) | |
| \beta | |
| i |
\Delta\sigmai
What this means is that before performing the inversion, the continuum components from both the optical depth and from the species cross sections must be removed. This is the important “trick” of the DOAS method. In practice, this is done by simply fitting a polynomial to the spectrum and then subtracting it. Obviously, this will not produce an exact equality between the measured optical depths and those calculated with the differential cross-sections but the difference is usually small. Alternatively a common method which is applied to remove broad-band structures from the optical density are binomial high-pass filters.
Also, unless the path difference between the two measurements can be strictly determined and has some physical meaning (such as the distance of telescope and retro-reflector for a longpath-DOAS system), the retrieved quantities,
\lbrace\Delta\sigmai\rbrace
To deal with this, we introduce a quantity called the airmass factor which gives the ratio between the vertical column density (the observation is performed looking straight up, with the sun at full zenith) and the slant column density (same observation angle, sun at some other angle):
\sigmai0=amfi(\theta)\sigmai
where amfi is the airmass factor of species i,
\sigmai0
\sigmai\theta
\theta
Some algebra shows the vertical column density to be given by:
\sigmai0=
| \Delta\sigmai | |
| amfi(\theta2)-amfi(\theta1) |
where
\theta1
\theta2