5. Stratospheric Ozone: An Introduction to Its Study
03 Mar 2014-
About: The article was published on 2014-03-03 and is currently open access. It has received None citations till now. The article focuses on the topics: Ozone layer.
Summary (3 min read)
Jump to: [REACTIONS IN A HYDROGEN-OXYGEN ATMOSPHèRE] – [REACTIONS AFTER OXIDATION OF MéTHANE] – [ATMOSPHèRE] – [and] – [SOLAR RADIATION] – [PHOTODISSOCIATION IN THE TROPOSPHèRE AND STRATOSPHèRE AND ITS EFFECTS] – [FINAL INTRODUCTORY REMARKS] and [CONCENTRATION Icm"'')]
REACTIONS IN A HYDROGEN-OXYGEN ATMOSPHèRE
- When an analysis of the various reaction rates is made, a certain number of them can be ignored, and for several years it was assumed [e.g.. Fig. 2 . Observed and calculated ozone profiles.
- Hunt. 1966; Leovy. 1969] that the reactions of OH and HO2 radicals with O and Oj were the essential reactions explaining the aeronomic behavior of stratospheric ozone.
- The normal photodissociation process (a,3) H2O + hv neS) + OH{Xm) (30) which can still occur in the stratosphère, is less important than the reaction process (29).
- This reaction may be introduced into the aeronomic chemistry of molecular hydrogen.
- The rate coefficient «20 should be of the same order of magnitude as 13,5, but no acceptable value has been found.
REACTIONS AFTER OXIDATION OF MéTHANE
- Methyl radicals, which are produced by oxidation processes of CH,, may react rapidly with atomic oxygen (c) CH, + O -H + HjCO + 67 Iccal (63û) with u rate coefficient [Slagle et al..
- According to Levy [1972] , CH,0,H either reacts with OH or is subject to photodissociation (c") CH,0,H + hv ^ CH,0 + OH (78) Finally, if methylperoxynitrite and methylperoxynitrate are formed, the photodissociation should be considered to be and (Oo) EQUATION Reactions of CH,, CH3O, and CHjO, with ozone have also been considered [Simonaitis and Heicklen, 1975a] .
ATMOSPHèRE
- The présence of nitrogen oxides in the upper atmosphère requires the production of atomic nitrogen [Nicolei.
- From this analysis of the various reactions of nitrogen trioxide, it is not clear if NO, can play a major rôle in stratospheric aeronomy.
- Among the various dissociation processes, the authors may consider the following: Cl, + hv{\ < 483 nm) -2CI (159a) is photodissociated in the stratosphère and troposphère by radiation of X > 300 nm [Seery and Britton.
and
- Thus the addition of nitrogen oxides NO and NO,, which destroy odd oxygen by various reactions involving ozone and atomic oxygen, must be considered with its counterpart, the photodissociation of NO, NO,, and NO, and the N formation, as production processes in addition to the photodissociation of molecular oxygen.
- Furthermore, the differential équation for nitric oxide must be written as foilows:.
- Thus the nitrogen oxide concentrations, and particularly those of HNOs, NO, and NO2, must dépend on atmospheric conditions in the lower stratosphère [Brasseur and Nicolet, 1973] , and their behavior will be related to the variation of the tropopause.
SOLAR RADIATION
- The authors knowledge of solar radiation in the ultraviolet which plays a rôle in the photodissociation of molecular oxygen is due to rocket and balloon data.
- The percentages are given for the spectral range AK = 500 cm"'; standard conditions prevail.
- There is therefore no doubt that the stratospheric ozone below its concentration peak is essentially due to a downward transport from the production régions Figure 20 is another illustration of this distribution of the ozone formation resulting from the atomic oxygen production with a peak in the upper stratosphère between 40 and 50 km even for overhead sun conditions.
- The température-altitude profiles indicate that the important différences occur between 10 and 20 km; they are related to the hcight of the tropopause and have therefore an effect on the rate coefficients in the lower stratosphère.
PHOTODISSOCIATION IN THE TROPOSPHèRE AND STRATOSPHèRE AND ITS EFFECTS
- The photodissociation in the lower régions of the terrestrial atmosphère is of particular interest, since it is the necessary process to start various chemical reactions.
- The ozone photolysis (see for example, Welge [1974] for a récent analysis of the photolysis of O», Hd, COj, and SO, compounds) occurs in the visible région in the spectral range of the Chappuis bands with production of oxygen molécules and atoms in their normal States.
- Its concentration dépends on the exchange processes between the stratosphère and troposphère.
- The absorption cross section of nitrous oxide varies within very low values less than 10"" cm^ between 310 and 250 nm, and its photodissociation coefficient is not greater than 10"' s"' at the stratopause and reaches only values less than 10"' S"' in the low stratosphère.
- The photodissociation rates are relatively small, and departures from photochemical equilibrium conditions are aiways the rule.
FINAL INTRODUCTORY REMARKS
- The authors have seen that it is aiways possible to résolve the theoretical problem of stratospheric ozone with the introduc-PHOTOOI SSOCIAT ION COEFFICIENT I sec"'l Fig. 37 . 1972] . tion of correct aeronomic équations and with the adoption oi the principal atmospheric parameters.
- The boundary conditions, which are used in stratospheric models, are not aiways adopted to varying atmospheric conditions.
- Seiler, 1974; Seiler and Schmidi, 1974] il may be pointed out that the CO concentration must be known with précision in the lower stratosphère in order to détermine the ratio n(OH)/«(H02).
- In the same way, the tropospheric ozone problem requires more attention, since a photochemical theory has been proposed by Chameides and Walker [1973.
CONCENTRATION Icm"'')
- Récent measurements by Schmidt [1974] and Seller and Schmidt [1974] lead to an almost constant mixing ratio ofO.55 ppm for tropospheric molecular hydrogen which can be taken as the normal mixing ratio above the tropopause level.
- Sampling [Ehhall, 1974] in the stratosphère at various latitudes is required in order to obtain enough vertical profiles to compare with the calculated vertical distributions of méthane and molecular hydrogen.
- It is not yet clear how the vertical and horizontal transports play their rôle [Wofsy et ai. 1967] , and even spécial sources [Deuser et al., 1973] .
- Récent measurements at ground level of HNO2 by Nash [1974] lead to mixing ratios from 1 to 10 ppb which must be explained by its various reactions with nitrogen oxides and hydroxyl and hydroperoxyl radicals.
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TL;DR: In 1969, 1970, and 1971 N 2 O measurements of sea water were carried out during three cruises in the open North Atlantic ocean as discussed by the authors, where water samples were taken from the sea's surface and from depths down to 3000 m at several stations.
Abstract: In 1969, 1970, and 1971 N 2 O measurements of sea water were carried out during 3 cruises in the open North Atlantic ocean. Water samples were taken from the sea's surface and from depths down to 3000 m at several stations. Surface water concentrations in the tropical-subtropical latitudes averaged 0.5 ?g N 2 O per liter sea water. For the range from 38.5° N to 48.5° N, an average of 0.4 ?g N 2 O per liter sea water was found. In the area of the Iceland—Faroe ridge, the surface water concentrations averaged 0.4 ?g N 2 O per liter' sea water when water temperatures were 10°C, and 0.5 ?g N 2 O per liter sea water when water temperatures were 5°C. The vertical N 2 O concentration profiles often show two maxima: a smaller one between 100 and 200 m and a large one between 400 and 1000 m with N 2 O concentrations up to 0.8 ?g per liter sea water. With the exception of a few samples, the measurements indicated that the North Atlantic sea water is supersaturated with N 2 O. Supersaturation values up to more than 100% were found in the upper layers of the sea water from the tropical-subtropical latitudes up to 48.5° N. Further north the N2O supersaturation of the sea water decreases. For the upper sea water layers down to 1000 m the following average values were obtained from vertical profiles: in tropical latitudes about 66% super-saturation, in subtropical latitudes about 47%, in the range from 38.5° N to 48.5° N about 42%, and in the area of the Iceland—Faroe ridge about 12–20% supersaturation. One may conclude that the North Atlantic ocean acts as a net source of atmospheric N 2 O. It is probable that the other oceans have the same ability. DOI: 10.1111/j.2153-3490.1974.tb01962.x
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TL;DR: Using the technique of flash photolysis-resonance fluorescence, absolute rate constants have been measured for the reaction H + O2 + M HO2+M over a temperature range of 220-360°K.
Abstract: Using the technique of flash photolysis-resonance fluorescence, absolute rate constants have been measured for the reaction H + O2 + M HO2+M over a temperature range of 220–360°K. Over this temperature range, the data could be fit to an Arrhenius expression of the following form:
The units for kAr are cm6/mole-s. At 300°K the relative efficiencies for the third-body gases Ar:He:H2:N2:CH4 were found to be 1.0:0.93:3.0:2.8:22. Wide variations in the photoflash intensity at several temperatures demonstrated that the reported rate constants were measured in the absence of other complex chemical processes.
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TL;DR: In this paper, a regression analysis was performed for six pressure levels (100 −mb) to examine the variability of water vapor concentration in terms of two components, a linear trend and an annual cycle.
Abstract: Monthly measurements of stratospheric water vapor concentration, initiated as an IQSY program, have continued from a site near Washington, D.C., and now constitute a six-year time series of homogeneous data which may be examined for evidence of stratospheric water vapor variability. A regression analysis was performed for six pressure levels (100–mb) to examine the variability of water vapor concentration in terms of two components, a linear trend and an annual cycle. A highly significant trend of increasing mixing ratio from 2 to 3 ppm is found for all pressure levels over the six-year interval. A significant annual cycle is indicated for the higher pressure levels. Study of the literature indicates that similar annual cycles and trends have been observed in the height of the tropical tropopause and in temperatures at or near the tropopause. It is suggested that variability in the drying potential of the tropical tropopause region leads to corresponding variability in stratospheric mixing ratio ...
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TL;DR: In this paper, a fast flow reactor with a fixed ESR detector and movable NO2 source (for generation of OH by the H + NO2 reaction) was used to measure the rate constants for CO + OH → CO2 + H (k1) and H2 + OH→ H2O + H(k4).
Abstract: Using a fast flow reactor with a fixed ESR detector and movable NO2 source (for generation of OH by the H + NO2 reaction) it was possible to measure the rate constants for CO + OH → CO2 + H (k1) and H2 + OH → H2O + H (k4) under pseudo‐first‐order conditions with negligible OH loss by OH + OH → H2O + O. Small losses of OH on the reactor wall were accurately taken into account, and data over an extended temperature range were obtainable. Both reactions show definite curvature in their Arrhenius plots over the range of direct measurement (298–915°K for k1 and 298–745°K for k4). Good agreement is found in comparisons with other well‐defined results. In the case of Reaction (4), a definitive experiment was performed to show that by far the dominant reaction path involves breaking the H2 bond, rather than the OH bond as in Reaction (1).
87 citations
87 citations