CATALYSTS FOR CO^2 REDUCTION
Photo-driven catalysts for CO 2 reduction have made use of
the versatile photochemistry and redox properties of Ru
complexes. Photo-excitation of Ru(bpy) 3 2+ (below, top panel)
results in formation of an excited state that reacts readily with
the sacrificial donor triethanolamine. The reduced Ru(bpy) 3 +
can then act as a source of electrons to drive a catalytic cycle
of the type shown in the bottom panel below (Pugh et al.
1991). In this cycle, another Ru complex catalyzes the
reduction of CO 2 to formate ion. Input of electrons is required
at two points in the overall cycle. The overall mechanism for
the catalytic reduction of CO 2 is complex, so that a great deal
of work remains to find optimal catalysts that are well-
coupled to the photochemical agents that use solar energy to
provide a source of electrons to drive the catalysts.
N
N N
N
Ru
+
CO
H
N
N N
N
Ru
0
CO
H
N
N N
N
Ru
0
CO
NCCH 3
N N
N
N
Ru
0
CO
O
-.
-.
O
H
-.
-.
O-
O
CH 3 CN
CO 2
e-
e-
H 2 O, CO 2
CH 3 CN, HCO 3 -
N
N N
N
N N
Ru
2+
N
N N
N
N
N
Ru
+
N(CH 2 CH 2 OH) 3 +N(CH 2 CH 2 OH) 3
decompositionproducts
hν
CATALYSTS FOR WATER OXIDATION
Catalysts with sufficient oxidizing power to split water remain
relatively rare. Yet, several recent catalysts based on Mn and
Ru have demonstrated water oxidation following addition of
strong oxidants to access the higher oxidation states of these
metals. As an example, the top panel shows the structure of
a Mn 2 complex that generates O 2 obtained from water using
NaOCl as an added oxidant (Limberg et al. 1999). The
mechanism of catalysis is shown in the lower panel. Thus far,
the turnover frequencies and the stability of water oxidation
catalysts remain low. In addition, coupling of a photo-driven
oxidant to these catalysts has not been accomplished.