Ch.2. Tracing the Hydrological Cycle
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Transcript of Ch.2. Tracing the Hydrological Cycle
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Ch.2. Tracing the Hydrological Cycle Craig’s meteroic relationship in global
fresh waterdD = 8d18O + 10 ‰ SMOW (Craig, 1961)
From IAEA-GNIPdD = 8.13d18O + 10.8 ‰ VSMOW
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Partitioning of isotopes through the hy-drological cycleIsotopic composition of ocean waters
○ The early oceans were isotopically depleted and warmer than today gradually enriched through Proterozoic and Phanerozoic time by exchange with isotopically enriched crustal rocks
○ The isotopic composition varies withSalinity (evaporation)Dilution by runoffIce melting (glacier retreat) etc.
See Fig. 2-2 & 2-3 on p.38.
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The atmosphere & vapour mass formation○ The troposphere contains more than 90%
mass (very little vapour circulates to the stratosphere)
○ The greatest supply (>70%) of vapor to the troposphere is from evaporation over the warm subtropical seas (Fig. 2-4 on p. 39)
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From http://www.agci.org/classroom/atmosphere/index.php
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From http://www.engineeringtoolbox.com/moisture-holding-capacity-air-d_281.html
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Isotopic equilibrium in water-vapor ex-change
○ For an equlibrium evaporation at 25oC,
d18Ov=d18Ow + e18Ov-w=0 + (-9.3)=-9.3 ‰dDv=dDw + eDv-w=0 + (-76)=-76 ‰
See Fig. 2-5 on p.40.
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Fig. 2-2 Enrichment of 18O and 2H in distilled water during evaporation of water under controlled conditions. Humidity h is 0% and temperature is 25°C. As the fraction of water remaining approaches 0, a Rayleigh distillation causes an exponential increase in the heavy isotopes. Under conditions of increasing humidity, exchange with the vapour phase reduces the exponential enrich-ment. Under conditions of high humidity, a steady state value is reached due to complete exchange with the vapour mass.
Humidity & kinetic evaporation
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Model for nonequilibrium evaporation over a water body. Arrows indicate relative fluxes of water between the mixed water column and the boundary layer, and between the boundary layer and the well mixed air column. Dif-ferences in the rate of diffusion of 18O to 16O and 2H to 1H impart a "kinetic" isotope depletion in the overlying air column.
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The maximum kinetic enrichment that this diffusive effect can impart is calcu-lated from our formula for diffusive fractionation of a gas in air (Chapter 1). In this case it is calculated for 18O in H2Ov from the boundary layer (bl) to the vapour reservoir of the open air water vapour (v):
Using the molecular mass of H218O (20), H2
16O (18), and air (mair = 28.8 for 79% N2 and 21% O2), gives De18Obl-v = 1.0323.
De18Obl-v = (a18Obl-v – 1) · 103 = 32.3‰
Similarly, 2H in the water vapour would be depleted by a maximum of:
DeDbl-v = (aDbl-v – 1) · 103 = 16.6‰
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○ Kinetic effects in terms of humidity (Gonfi-antini, 1986)De18Obl-v = 14.2 (1–h) ‰ DeDbl-v = 12.5 (1–h) ‰
○ The total fractionation between the water col-umn and the open air is then the sum of the fractionation factor for equilibrium water-vapour exchange (el-v) and the kinetic factor (Debl-v)d18Ol – d18Ov = e18Ol-v + De18Obl-v
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Isotopic enrichment in evaporating water and the effect of humidity. Slopes are approximations of early portion of each curve near the GMWL (heavy line) (modified from Gonfiantini, 1986
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Deuterium excess “d” in meteoric water
See Fig, 2-9. & 2-10 on p. 44
Dansgard (1964):d= dD-8d18O
See Fig. 2-11 & Table 2-6. on p. 45
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Atmospheric mixing and global atmospheric water vapor○ Craig & Gorden (1965): mean isotopic com-
position of global precipitationd18O=-4‰ , dD=-22‰
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