Tabelle der Diffusionskoeffizienten

Zur Berechnung der elektrischen Leitfähigkeit¹ verwendet aqion die in den folgenden drei Tabellen angegebenen Diffusionskoeffizienten. Die Spalten bedeuten:

z	Ladungszahl des Ions
D_i	Diffusionskoeffizient des Ions i aus Ref. [P] bzw. [V]
\(\Lambda_{m,i}^{0}\)	molare Grenzleitfähigkeit des Ions i – berechnet nach Gl. (1)
\(\Lambda_{eq,i}^{0}\)	Äquivalent-Grenzleitfähigkeit des Ions i gemäß \(\Lambda_{eq,i}^{0} = \Lambda_{m,i}^{0}/\mid\! z_i\mid\)

Vorgehensweise bei der Auswahl der Diffusionskoeffizienten: Priorität hatten die in phreeqc.dat [P] gelisteten Werte, anschließend wurde mit Diffusionsdaten von [V] ergänzt.

Anorganische Kationen

Kation	\|z\|	D_i /10^-9 [m²/s]	\(\Lambda_{m,i}^0\) [S cm²/mol]	\(\Lambda_{eq,i}^0\) [S cm²/mol]	Ref
Ag+	1	1.648	61.9	61.9	[V]
Al+3	3	0.559	188.9	63.0	[P]
Ba+2	2	0.848	127.4	63.7	[P]
Be+2	2	0.599	90.0	45.0	[V]
Ca+2	2	0.793	119.1	59.6	[P]
CaHCO₃⁺	1	0.506	19.0	19.0	[P]
Cd+2	2	0.717	107.7	53.8	[P]
Co+2	2	0.732	110.0	55.0	[V]
Cr+3	3	0.595	201.1	67.0	[V]
Cu+2	2	0.733	110.1	55.0	[P]
Fe+2	2	0.719	108.0	54.0	[P]
Fe+3	3	0.604	204.1	68.0	[V]
H+	1	9.310	349.6	349.6	[P]
Hg+2	2	0.913	137.2	68.6	[V]
K+	1	1.960	73.6	73.6	[P]
Li+	1	1.030	38.7	38.7	[P]
Mg+2	2	0.705	105.1	53.0	[P]
MgHCO₃⁺	1	0.478	18.0	18.0	[P]
Mn+2	2	0.688	103.4	51.7	[P]
Na+	1	1.330	50.0	50.0	[P]
NH4+	1	1.980	74.4	74.4	[P]
Pb+2	2	0.945	142.0	71.0	[P]
Sr+2	2	0.794	119.3	59.6	[P]
UO2+2	2	0.426	64.0	32.0	[V]
Zn+2	2	0.715	107.4	53.7	[P]

Anorganische Anionen

Anion	\|z\|	D_i /10^-9 [m²/s]	\(\Lambda_{m,i}^0\) [S cm²/mol]	\(\Lambda_{eq,i}^0\) [S cm²/mol]	Ref
Br-	1	2.010	75.5	75.5	[P]
Cl-	1	2.030	76.2	76.2	[P]
CO3-2	2	0.955	143.5	71.7	[P]
CN-	1	2.077	78.0	78.0	[V]
CNO-	1	1.720	64.6	64.6	[V]
CrO4-2	2	1.132	170.0	85.0	[V]
F-	1	1.460	54.8	54.8	[P]
H2AsO4-	1	0.905	34.0	34.0	[V]
H2PO4-	1	0.846	31.8	31.8	[P]
HCO3-	1	1.180	44.3	44.3	[P]
HPO4-2	2	0.690	103.6	51.8	[P]
HS-	1	1.730	65.0	65.0	[P]
HSO4-	1	1.330	50.0	50.0	[P]
I-	1	2.045	76.8	76.8	[P]
KSO4-	1	0.746	28.0	28.0	[P]
MnO4-	1	1.632	61.3	61.3	[V]
MoO4-2	2	1.984	298.0	149.0	[V]
NaCO3-	1	0.585	22.0	22.0	[P]
NaSO4-	1	0.618	23.2	23.2	[P]
NO2-	1	1.910	71.7	71.7	[P]
NO3-	1	1.900	71.4	71.4	[P]
OH-	1	5.270	197.9	197.9	[P]
PO4-3	3	0.612	206.8	68.9	[P]
S-2	2	0.731	109.8	54.9	[P]
SeO4-2	2	1.008	151.4	76.7	[V]
SO4-2	2	1.070	160.7	80.4	[P]

Organische Anionen (Ref. [V])

Org. Anion	\|z\|	D_i /10^-9 [m²/s]	\(\Lambda_{m,i}^0\) [S cm²/mol]	\(\Lambda_{eq,i}^0\) [S cm²/mol]
Acetate-	1	1.089	40.9	40.9
Benzoate-	1	0.863	32.4	32.4
Butyrate-	1	0.868	32.6	32.6
Citrate-3	3	0.623	210.6	70.2
Dihydrogencitrate-	1	0.799	30.0	30.0
Formate-	1	1.454	54.6	54.6
Hydrogenoxalate-	1	1.070	40.2	40.2
Isovalerate-	1	0.871	32.7	32.7
Lactate-	1	1.033	38.8	38.8
Malate-2	2	0.783	117.6	58.8
Maleate-2	2	0.824	123.8	61.9
Oxalate-2	2	0.987	148.3	74.1
Phenylacetate-	1	0.815	30.6	30.6
o-Phtalate-2	2	0.696	104.6	52.3
m-Phtalate-2	2	0.728	109.4	54.7
Pivalate-	1	0.849	31.9	31.9
Salicylate-	1	0.959	36.0	36.0
Suberate-2	2	0.479	72.0	36.0
Succinate-2	2	0.783	117.6	58.8
Tartarate-2	2	0.794	119.3	59.6

Referenzen

[P] PhreeqC (Version 3) – A Computer Program for Speciation, Batch-Reaction, One-Dimensional Transport, and Inverse Geochemical Calculations; Diffusion coefficients taken from thermodynamic database “phreeqc.dat”

[V] Petr Vanýsek: Ionic conductivity and diffusion at infinite dilution, Handbook of Chemistry and Physics, CRC Press, 1992/93 edition. Boca Raton, 1992. pp. (5-111)-(5-113).

Fußnoten

Berechnung erfolgt nach 10 – siehe hier. ↩

[last modified: 2020-12-05]