Stable Isotopes

stable isotopes most commonly used in isotope hydrology (Tab)
natural abundances of isotopes (Tab)
encyclopedia entry for Harold C. Urey
GMWL (Fig)
temperature dependence of equilibrium fractionation (Fig) (Tab)
quantitative description of equilibrium and kinetic fractionation (Fig)
a_kis a function of 1-h (data for smooth ocean) (Tab)
fractionation of oxygen isotopes during condensation of water from vapor at 25^oC according to the Rayleigh fractionation (Fig)
network (Fig), operational network (Fig)
GMWL (Fig)
Isotopes in the water cycle (Fig)

stable isotopes most commonly used in isotope hydrology (Tab)
we will focus here on the stable isotopes of H and O
relative abundance of H and O isotopes in terrestrial waters

	Isotope	average abundance
Hydrogen	¹₁H	0.99985
	¹₂H	0.00015
	³₁H	10^-16 to 10^-18
Oxygen	¹⁶₈O	0.99757
	¹⁷₈O	0.00038
	¹⁸₈O	0.00205

D, was first isolated by the Columbia chemist Harold C. Urey in 1931.
stable isotope ratios are typically measured in the so-called d notation:

d = (R_sample-R_standard)/R_standard * 1000; R = [¹⁸O]/[¹⁶O] etc.

so for example: d¹⁸O = -10 ‰ means that the sample is depleted relative to a standard in ¹⁸O by 1%

Standards

the original standard was proposed by Harmon Craig in 1961

SMOW ("Standard Mean Ocean Water") which never existed but was calibrated relative to a sample from the Potomac River (STD NBS-1)
(¹⁸O/¹⁶O) _SMOW = 1.008 (¹⁸O/¹⁶O) _NBS-1 = (1993.4 ± 2.5) * 10^-6
(²H/¹H) _SMOW = 1.008 (²H/¹H) _NBS-1 = (158 ± 2) * 10^-6

subsequently the IAEA (International Atomic Energy Agency) prepared a standard water from distilled seawater that was modified to have an isotopic composition close to SMOW

(¹⁸O/¹⁶O) _VSMOW = (2005.2 ± 0.45) * 10^-6
(²H/¹H) _VSMOW = (155.76 ± 0.05) * 10^-6

for isotopically very depleted samples another standard, SLAP ("Standard light Antarctic Precipitation")

d¹⁸O_SLAP = -55.50 ‰ VSMOW
d²H_SLAP = -428.0 ‰ VSMOW

the VSMOW is the currently accepted since ~ 3 decades
often measurements are reported in SMOW although they use VSMOW as reference (bad practice!)
for isotopic measurements on carbonates, organic carbon and hydrocarbons the PDB standard is used

H. Craig introduced the PDB standard in 1957 (PDB = sample taken from an internal calcite structure from a fossil Belemnitella americana from the Cretaceous Pee Dee Formation in South Carolina
after the standard was used up it was replaced by VPDB, which is supposed to be identical to PDB
d¹⁸O_VSMOW = 1.03091 * d¹⁸O_VPDB + 30.91 ‰

precision of measurements is of the order of 0.1 ‰ for d¹⁸O and 1 ‰ for d²H (=dD)

Fractionation

Harmon Craig found in 1961 that d²H and d¹⁸O in precipiotation are related (Fig)
he defined the Global Metoric Water Line (GMWL, in SMOW):

d²H = 8* d¹⁸O + 10 ‰

Notation

isotope fractionation occurs any thermodynamic reaction due to the differences in the reaction rates of different molecular species
it is expressed by the fractionation factor a, which is the ratio of the isotope ratios for the reactant and product:

a = R_reactant/R_product

for example for a water/vapor system:

a¹⁸O_water-vapor = (¹⁸/¹⁶O)_water/(¹⁸O/¹⁶O)_vapor> 1

Equilibrium fractionation

heavy isotopes are typically enriched in the more condensed phases
in case of the water/vapor system the lighter molecule has an easier time to break up the hydrogen bonds and will be enriched in the vapor phase, in the case of oxygen isotopes by 1%
temperature dependence of the fractionation (Fig)
the fractionation is often expressed as deviation from 1 in ‰:

a_e= 1 + e_e

for example, at 20^oC the equilibrium fractionation factors are: e_e(²H) = 85 ‰, e_e(¹⁸O) = 9.8 ‰ ( d²H vs d¹⁸O Fig)

T (^oC)	e_e(²H) (‰)	e_e(¹⁸O) (‰)	e_e(²H) / e_e(¹⁸O)
0	112.3	11.7	9.6
10	97.7	10.7	9.1
20	85.0	9.8	8.7
30	74.0	9.0	8.2

quantitative description: consider the following situation (Fig)
for the liquid phase we can write:

d N_i/d N = 1/a_e* N_i/N

since R = N_i/N: dR/dN = 1/N (dN_i/dN - N_i/N) = R/N (1/a_e-1) this equation can be integrated: R = R_o * (N/N_o)^(1/ae
-1)= R_o * f ^(1/ae
-1) with f being the residual water fraction

(1/a_e-1) = (1/(1+ e_e)-1) ~ -e_e

this formula describes the so-called Rayleigh fractionation

Non-equilibraium or 'kinetic' fractionation

in case the relative humidity drops below 100% (h<1) (Fig) the water molecules have to penetrate the molecular boundary layer above the water which reults in a kinetic fractionation

a_k~ (D/D_i)^m > 1
a_k= 1 + e_k

a_kis a function of 1-h (data for smooth ocean)

h	e_k(²H) (‰)	e_k(¹⁸O) (‰)
1	0	0
0.9	-0.5	-0.6
0.8	-1.1	-1.2
0.5	-2.6	-3.0

kinetic fractionation does influence the fractionation of both isotopes in similar ways (different from equilibrium fractionation!)
( d²H vs d¹⁸O Fig)

Combined fractionation

the total fractionation can then be described in the following way:

for the liquid: R/R_o = (N/N_o)^{(1/(ae*ak)
-1)}~ f ^{-(ee + ek)}
for the vapor: R/R_o = 1/(a_e*a_k) * f ^{-(ee + ek)}

when looking at the formation of precipitation the process is reversed, but is usually presumed to be an equilibrium fractionation
fractionation of oxygen isotopes during condensation of water from vapor at 25^oC according to the Rayleigh fractionation (Fig)

Global network of Isotopes in Precipitation (GNIP)

maintained by the IAEA/WMO
measures ³H, ²H, and ¹⁸O
complete network (Fig), operational network (Fig)
GMWL is the compilation of all measurements in precipitation (Fig)
the isotopes of the water molecule, tritium, deuterium and oxygen-18, label the global water cycle (Fig)

powerpoint file with animations

Resources

IAEA/WMO Global Network of Isotopes in Precipitation (GNIP)
GNIP booklet
Environmental Isotopes in the Hydrological Cycle : Principles and Applications (IAEA website)

very comprehensive on-line resource