- Source: Palladium-hydrogen electrode
The palladium-hydrogen electrode (abbreviation: Pd/H2) is one of the common reference electrodes used in electrochemical study. Most of its characteristics are similar to the standard hydrogen electrode (with platinum). But palladium has one significant feature—the capability to absorb (dissolve into itself) molecular hydrogen.
Electrode operation
Two phases can coexist in palladium when hydrogen is absorbed:
alpha-phase at hydrogen concentration less than 0.025 atoms per atom of palladium
beta-phase at hydrogen concentration corresponding to the non-stoichiometric formula PdH0.6
The electrochemical behaviour of a palladium electrode in equilibrium with H3O+ ions in solution parallels the behaviour of palladium with molecular hydrogen
1
2
H
2
=
H
a
d
s
=
H
a
b
s
{\displaystyle {\tfrac {1}{2}}\mathrm {H} _{2}=\mathrm {H} _{ads}=\mathrm {H} _{abs}}
Thus the equilibrium is controlled in one case by the partial pressure or fugacity of molecular hydrogen and in other case—by activity of H+-ions in solution.
E
=
E
0
+
R
T
F
ln
a
H
+
(
p
H
2
p
0
)
1
/
2
{\displaystyle E=E^{0}+{RT \over F}\ln {a_{\mathrm {H} ^{+}} \over ({\frac {p_{\mathrm {H} 2}}{p^{0}}})^{1/2}}}
When palladium is electrochemically charged by hydrogen, the existence of two phases is manifested by a constant potential of approximately +50 mV compared to the reversible hydrogen electrode. This potential is independent of the amount of hydrogen absorbed over a wide range. This property has been utilized in the construction of a palladium/hydrogen reference electrode. The main feature of such electrode is an absence of non-stop bubbling of molecular hydrogen through the solution as it is absolutely necessary for the standard hydrogen electrode.
See also
Dynamic hydrogen electrode
Reversible hydrogen electrode
References
External links
Electrochimica Acta
Kata Kunci Pencarian:
- Seng
- Galium
- Vanadium
- Palladium-hydrogen electrode
- Standard hydrogen electrode
- Reversible hydrogen electrode
- Reference electrode
- Palladium hydride
- Palladium
- Dynamic hydrogen electrode
- Hydrogen technologies
- Hydrogen production
- Fuel cell