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Catalysis and photoelectrochemistry on ruthenium disulphide surfaces
Materials
14 (1986)
Chemistr.v and Physics.
REVIEW
113
113 - 12 1
PAPER
CATALYSIS
AND PHOTOELECTROCHEMISTRY
ON RUTHENIUM
DISULPHIDE
SURFACES
A.J. McEVOY Ecole Polytechnique
Institut de Chimie Physique, 1015 Lausanne (Switzerland)
F&&rale
de Lausanne,
ABSTRACT
The effective catalytic behaviour of ruthenium disulphide for the hydrodesulphurisation (HDS) of organic sulphur compounds has been established. As a semiconductor electrode in a photoelectrochemical cell, the n-type material functions as a stable photoanode for oxygen evolution. As an electrocatalyst on cadmium sulphide colloids, it promotes the photochemical dissociation of H2S, and the associated evolution of hydrogen is then observed at a high rate. The present work reviews current knowledge of the catalytic and electrocatalytic behaviour of this compound.
INTRODUCTION The demands made on the catalysts stantly more severe as the industry taining
significant
amounts
current use are based kel-promoted
of sulphur
on transition
molybdeneum
in particular,
of effective
technologies
catalysts:
hydrogen,
and photoelectrochemical
catalysis
minimises
sulphides,
energy
such as Co2NiSk,
for the production trochemistry,
0254-0584/86/$3.50
supported
promoted
kinetics
(HDS)
[I,;?].
cells
for the desired
of
In electrolysis,
effects.
as cathode
electrolysis
A recent
for the production
of solar energy.
have been investigated in alkaline
RuS2
in
and nic-
for their future on the
systems
losses due to overpotential
of hydrogen
catalytically
are dependent
electrolytic conversion
cobalt-
on alumina.
disulphide,
con-
con-
The catalysts
typically
of hydrodesulphurisation
by the use of ruthenium
Two other energy-related development
sulphides
have become
'sour' crudes,
compounds.
sulphides,
for improvement
refining
increasingly
and nitrogen
metal
or tungsten
study has shown the potential catalysts,
used in petroleum processes
Transition
metal
electrocatalysts [3]. In photoelecreaction,
e.g.
0 Elsevier Sequoia/Printed in The Netherlands
114 water splitting population
otherwise
undesirable provides
to evolve hydrogen
competing
tensively
investigated
heterogenous
reduction
gies, in addition
processes,
and prospective
to the theoretical
there is at present
significant
interest
motivation
dioxide
[4] it has been ex-
colloidal
particles
in
that the ox-
[5-81. The investigation
of the
as an alternative
was therefore
applications
for
as a film on semiconduc-
itself a semiconductor,
for anodic charge transfer
With these present
interface
there is now evidence
processes
disulphide,
carrier
Since ruthenium
surface
with semiconductor
systems. However,
cathodic
of ruthenium
electrode
either deposited
or associated
photochemical
ide also promotes properties
such as photocorrosion.
oxygen evolution
as a catalyst,
surfaces,
deplete the minority
at the semiconductor/electrolyte
reactions
a very efficient
tor electrode
catalyst
available
and oxygen,
initiated
in energy-related
in clarifying
[g].
technolo-
catalytic
mechanisms
for the study of the ruthenium
di-
chalcogenides.
PHYSICAL
PROPERTIES
It has long been known that ruthenium structure
disulphide
adopts the pyrite,
[lo-121. A somewhat more recent confirmation
measurement
of the lattice parameters,
rite structure
is basically
a unit cell of edge length
C-2 type
of the structure,
was that of Sutarno
with
et al. [131. The py-
cubic (space group Pa 3) with four formula units to 5.61 8, located
Ru:
(4)
000; 0 ; $; 2 0 ;; ; ; 0.
s :
(SC)
+(uuu;
as follows:
;+u, s-u, ii; ;, ;+u, a-u; i-u, U, ;+u)
where u = 0.39 The sulphur
atoms are therefore
interpenetrating
that of the ruthenium
the pyrite structure, For ruthenium magnetic
in pairs in a F.C. cubic sublattice
atoms. By analogy with the prototype
FeS2, an oxidation
state of +2 is assigned
(d7 s') this implies a d6 ion in the crystal
properties
and associated
each filled by two electrons splitting
placed
low-spin
with opposed
from the upper, empty, d-levels
of
to the cation.
, and given its dia-
state, three low energy d-levels
spins separated
due to crystal
field
[lb]. The energy gap is therefore,
de-
fined by d-levels. The diamagnetic a preparation as prepared,
behaviour
of RuS 2, just noted,
reaction has gone to completion is normally
n-type,
ved in certain iron-ruthenium
is a convenient
[15]. The semiconducting
116-181 alth ough p-type behaviour
pyrite
width of the band gap is presently
indicator
solid solutions,
FexRul_xS2
in dispute. Originally
that
crystal,
may be obser[16]. The
a figure of 1.8 ev was
115 accepted, [lg].
based
However,
on diffuse
eV, the experimental crystals.
data being
From the relationship
from the reflectance (hv = Eg + ka2), However,
optical
reflection
derived
from reflectance
between
the absorption
data) and the photon
b) data extend only to photon
energies
below
is also inconclusive.
on this effect using
on the basis
root of quantum theless
1.8 eV is remarkably
sintered
a significant
response
[20] and was interpreted
defects
showing
of energy below
using
in the material.
with the presence
for Eg therefore
the
gap of 1.8
of some 1% of the ruthenium
a significant
of the transition
sin-
However,
followed by a higher
photoresponse
to infrared
[16,211 perhaps though an elevation
tion (hv = 1.4 eV) was obtained lence band edge associated
the square edge. None-
in terms of an energy gap of 1.3 eV
cross section,
eV. It is further noted that by substitution by iron, a semiconductor
deduced
in terms of donor levels close to the
be interpreted
with a low transition
vely by a modification
between
at the red end of the spectrum was observed
could alternatively
a
at single
this gap being
to photons
ob-
[l6,1.7]at single crystal surfaces. An even
persistent
effect
value
and they suggested
from the same laboratory,
energy near the absorption
with structural
finitive
spectra at semiconductor-elecet al. [9] made the initial
linear relationship
Fermi level and associated
(indirect)
edge
region near the previ-
RuS2 electrodes,
in later work
and the photon
spectra,
photoresponse
tered electrodes
(calculated
on.
Guittard
of an apparently
efficiency
in published
stronger
on single
:
[17] the value of 1.85 eV is accepted,
electrodes
as indirect
coefficient
and the spectral
for the energy gap from photoresponse
value of 1.3-1.5 eV. However, crystal
measurements
1.6 eV. That absorption may there-
value of 1.8 eV is not reported
interfaces
servations
Sat@eS
at a figure of 1.3
are not reported;
fore be other than the band gap effect,
Evidence
POW&red
energy close to the absorption
apply to these conclusions
a) the absolute absorption coefficients
trolyte
on
it was deduced that the band gap is indirect.
two reservations
ously reported
measurements
et al. [la] arrives
the recent work of Bichsel
of iron d electrons,
crosssection
awaits further
radia-
of the va-
or alternati-
for the indirect
experimental
sites
evidence,
gap. A dealthough
the lower value now appears more probable.
MATERIAL
PREPARATION
There is a direct
synthesis
route at high temperature
17,18,22,23] or by heating a subsulphide quartz
tube sealed under vacuum.
so the heating
of ruthenium
This reaction
must be slow and progressive.
from the elements
with sulphur
is strongly
Determination
[g,
[13] in a
exothermic
113,181
of the stoichiometry
116 of the material
so prepared
indicates
that the pyrite
tained despite
some sulphur
deficiency
phur excess is used in the synthesis,
produced
Reported
procedures
annealed,
hours
procedure
a 5% sul-
mixture
[24]. To form electrodes, may be sintered,
the
and there[20].
are either chemical vapour trans-
as transport
agent, with a 1040 - 102O'C
across the sealed quartz ampoule being maintained
or by crystallisation
at 800'C
at 1OOO'C in a sulphur atmosphere
for single crystal growth
gradient
[181;
to completion
typically
port with IC13 or an IC13-S2C12 temperature
[15,23]. At SERI, for example,
in the synthesis
after where necessary
can be main-
and the sealed tube is maintained
for three days to bring the reaction microcrystals
structure
[16,17,251
from a tellurium
for 700
or bismuth
[26l
melt. Ambient
temperature
preparation
procedures
[15] using a metathesis
reaction
RuC13 + 2(NH4)HS
RuS2 + HCl + 2NHqC1
This reaction
_I)
is generally
of the type
for RuS2 have also been reported
:
(1)
carried out in a nonaqueous
clusion of oxygen, to avoid any oxide or hydroxide the initial material
sample of RuC13 should also be anhydrous.
has been mentioned
[2] but problems
solvent,
formation
and with the ex-
[2,l5]. Equally,
Use of an 'RuC14' starting
of stability
and handling
of such a
compound may be anticipated. It must be recognised a short-range in contrast bility
of these reactions
order of the RuS2 type. The filtered precipitate
to the stability
is non-zero.
An annealing
that the product
of the pyrite RuS2 crystal.
Only a featureless
in H2S at a temperature
lise this product.
can only be obtained
to crystallise,
diffraction
after annealing
pattern
and the density
at 850'~ [15]. The structure
of ruthenium
fore be questionable;
there was for a time the suggestion
a charge-neutralised
E.S.C.A. species
studies have established
free elemental E.S.C.A. tainty).
sulphur
features,
formed by low temperature
co-colloid
(-2), and the presence
of ruthenium
the oxidation
of some sulphate
is obtainable. to stabi-
of 6.23
diamagk 0.03
and stoichio-
alone must there-
that the product was
and sulphur. However.
state of the sulphur contamination,
(due to the small chemical
its oxidation
pattern
suscepti-
but a well-defined
metry of any sulphide
merely
can be pyrophoric,
The magnetic
greater than 25O'C is necessary
At 350°C it begins
netic solid giving the pyrite
X-ray diffraction
show, at best, only
our
(dimer)
but certainly
shifts of the ruthenium
state is more difficult
to specify with cer-
no
117 One advantage sulphide
of the metathesis
deposits
cles of other semiconductors exposed
procedure
is that ruthenium
or colloidally
suspended
di-
parti-
27,28 . Here the surface or colloid is
e.g. C&3
to RuC13 or K2RuC16
ion introduced,
preparation
may also be laid on surfaces
in aqueous
solution
for example, by bubbling
, which then reacts with sulphide
H2S or as a NaHS solution.
ELECTROCHEMISTRY In the initial work with sintered gen evolution current
in darkness with a surprisingly
density
trolyte,
of 4.5 ITLO. cm
-2
trode surface was only slightly
cathodic
anodic dark current
terface.
with an essentially
In an alternative
perspective
RuS2 electrode
[16,171. While hydrogen
electrode
dark reaction
surface
Mott-Schottky tigations,
RuS2 electrodes
effects
close to the H20/02
:an be obtained
redox potential The chemical
tal electrode
beha-
more conventional
beha-
potentials
in dark-
[16,17,18I.
dependent
associated
Linear
potential
at -0.48 V
with the observed is however
state recombinatLon
a significant
of the surface
Only conis
photocurrent
has been explained
t28l.
on-
subject to
with this photocurrent
The fact that a continuous
states defining
inves-
on light intensity.
anodic potential
and photocorrosion
'd' nature of the electron
of that
potential.
in the single-crystal
a flat-band
A fur-
and the sintered
is the reduction
does it rise to represent
reaction
with surface
is very stable,
The non-ideal
hydrogen
This photoresponse
only at this relatively
of competition
to the pure
elicited
is compatible
and is not linearly
rerified as oxygen evolution
of deep donor states at
at cathodic
(l/C2 vs V) have been obtained indicated
in-
evident.
electrolytes,
of which
surface
solid-electrolyte
both on the single-crystal
(pH 1). This value
of that
The ef-
under anodic bias is no longer observed.
for anodic photoeffects.
tinous photocurrent.
the basis
is, however,
observed
the extrapolation
strong transient
but it was suppres-
of the oxidised
semiconductor.
just anodic of the reversible
(NHE) in acid electrodes set potential
in the occured
already mentioned.
[171 the charging
in oxygen-saturated
plots
potential,
ohmic contact
is still evolved
ness, the dark oxygen evolution
oxygen at potentials
the elec-
by a hysteresis
leading to a 'metallic'
may give a degenerate
Later work on single-crystal
ther cathodic
hydrogen
oxygen evolution
semiconductor,
these anodic potentials
viour
in a 0.1 M KOH elec-
The onset of an anodic photocurrent
and associated
viour of the sintered
was observed (a
sweep in the anodic sense prior to the appearance
fect may be associated with the underlying
[9,20] oxy-
Under these conditions
as evidenced
oxidised,
of the reversible
a potential
low overpotential
difference).
anodic region of the voltammogram. at a potential
RuS2 electrodes
with a Pt counterelectrode,
under a 1.5 V potential
sed during
polycrystalline
on
The single-crysis minimal,
the valence
due
and conduc-
118 tion band edges. In contrast, in the diselenide and ditelluride of ruthenium there is increasing photocorrosion,giving Ru02 and chalcogenate ion, associated with the increasing mixing of ruthenium d and chalcogen p electron states in the band structures of the compounds. For ruthenium disulphide, then, the dark hydrogen evolution, the oxygen-evolving photoeffect and the Mott-Schottky data are presented as evidence for a valence band edge close to the H20/02 redox potential, and the conduction band edge at some -0.5 V (NHE) in darkness; this would imply a band gap of 1.8 eV [l'i']. Photoelectrochemicalexperiments then show that those band edges become unpinned under illumination in the presence of an oxidisable species in aqueous solution; the potential at which a continuous photocurrent is established is displaced snodically with electrolyte redox potential over a wide range, from -0.48 V (NHE) for a sulphide electrolyte to +1.23 V (NHE) for oxygen evolution. The unpinning, and by consequence the anodic onset for photoevolution of oxygen, makes RuS2 an unfavorable candidate for energy conversion by photolysis of water: it also makes credible the narrower band gap (1.3 eV).
PHOTOCHEMICAL CATALYSIS BY RUTHENIUM DISULPHIDE Firely divided cadmium sulphide has been loaded with a ruthenium sulphide by a metathesis reaction (1) in the presence of an aqueous suspension of the CdS particles, followed by drying and annealing in a H2S atmosphere [27,281. For the photochemical dissociation of H2S in aqueous solution, this catalysed CdS suspension is some seven times more effective than Ru02-loaded material [29]. The RuS2 catalyst has the additional advantage of long-term stability. By spectral photoresponse it was confirmed that the CdS was the active semiconductor for photoexcitation, with an onset at 520 nm, hv = 2.4 eV. The function of the RuS2 as a catalyst is therely established, though it is not clear whether it influences preferentiallythe kinetics of the anodic or cathodic reaction
DESULPHURISATIONAND HYDROPROCESSINGREACTIONS These provide the most probable short-term economically significant application, and petroleum industry laboratories have been investigatingRuS2 catalysts for hydrodenitrogenation1301 HDN and hydrodesulphurisation[1,2] HDS of organic compounds for some time. For desulphurisationa systematic preparation of, and a comparison of the catalytic effiency of, a series of metal sulphides have been carried out. Model organosulphur compounds were then treated in an autoclave reactor in the presence of these test catalysts, the products being monitored by mass spectroscopy or gas chromatography.For example, the thermal desulphurisa-
119 tion of tertiary butyl thiol to yield a butene proceeds over an RuS2 catalyst to completion [311 :
(CH~)CSH
*,
(cH~)~c=CH~ + H2s
(2)
RuS2 This by analogy with the dehydration of the corresponding alcohol over a metal oxide catalyst 1321. 2oo"c ~---& 2
(CH2)3COH
(cH~)~c=cH~ + H~O
A useful reference compound for hydrodesulphurisation,HDS, is dibenzothiothene. Among the transition metal sulphides, the catalytic activity for this reaction varies by three order of magnitude. While the sulphides of the first row transition metals show a low and fairly constant activity, those of the second and third row show a significant dependence on location in the periodic table peaking sharply with the sulphides of ruthenium (2nd row) and osmium (3rd row) ('volcano curve', 1,2). During operation of the HDS reaction the ruthenium compound gradually becsme substoichiometricin sulphur. It is generally accepted that sulphur vacancies on the catalyst surface provide the reaction sites for HDS [33],
such vacancies occuring particularly easily in pyrite RuS2, where the
sulphur atoms occur in pairs. However, the interpretationof this catalytic behaviour in terms of the electronic, structural and chemical properties of the material is only now evolving [34], as is consideration of RuS2 as a model for the design of new catalysts of sulphides of base metals with enhanced activation due to selective surface alloying methods [35].
CONCLUSION Ruthenium disulphide is a promising material for the thermal catalytic processing of organic sulphur and nitrogen compounds in petroleum refining. It also has interesting photoelectrochemicalbehaviour, and photochemical catalytic properties. It is a useful model system for the study of catalytic mechanisms. Single crystals, polycrystalline samples and loaded colloids have been prepared and evaluated. However, materials improvement is still required, and characterisation of several physical and chemical parameters of RuS2 is still incomplete.
ACKNOWLEDGEMENTS Contact with Prof. Dr. H. Tributsch and Dr. A. Mackor was promoted by the European Community 'Stimulus'programme, contract STI-005-J-C (CD). Discussions
120 with Prof. J. Cunningham were useful. Prof. M. GrEtzel encouraged this present work, which is currently supported by the Swiss National Fund for Scientific Research.
REFERENCES R.R. Chianelli, in J.P. Bonnelle, B. Delmon and E. Derouane (eds.), Surface Properties and Catalysis by Non-metals, NATO AS1 Series C, no 5, Oct. 1982, Reidel, Dordrecht NL, 1983, p. 361. T.A. Pecoraro and R.R. Chianelli, J. Catalysis, 67 (1981) 430. H. Vandenborre and L.H. Baetslg, Euroreport EUR 7626 EN, Commission of the European Communities, Luxembourg, 1982. G. Lodi, E. Sivieri, A. de Battista and S. Trasatti, J. Appl. Electrochemistry. 8 (1978) 135. W. Gissler and A.J. McEvoy, in D.O. Hall, W. Palz and D. Pirrwitz (eds.), Solar Energy in the European Community Series D, Vol. 2, Reidel, Dordrecht NL, 1983, p. 140. A.H.A. Tinnemans, T.P.M. Koster, D.H.M.W. Thewissen and A. Mackor, op. cit. p. 86. P. Keller, A. Moradpour and E. Amouyal, op. cit., p. 121. D. Meisser, R. Memming and B. Kastening, op. cit., p. 111. R. Guittard, R. Heindl, R. Parsons, A.M. Redon and H. Tributsch, J. Electroanal. Chem., 111 (1980) 401. 10 W.F. de Jong and A. Hoog, Rec. Trav. Chim., 46 (192'7)173. 11 I. Oftedal, Z. Phys. Chem. (LeipziP), 135 (1928) 291. 12 R.W.G. Wyckoff, Crystal Structures, Interscience.New York, 1963, p. 348. 13 0. Sutarno, 0. Knop and K.I.G. Reid, Can J. Chem., 45 (1967) 1391. 14 F. Hulliger and E. Mooser, J. Phys. Chem. Sol., 26 (1965) 429. 15 J.D. Passaretti, R.C. Collins, A. Wold, R.R. Chianelli and T.A. Pecoraro, Mat. Res. Bull., 14 (1979) 1167. 16 H.-M. Kiihneand H. Tributsch, J. Electrochem. Sot., 130 (1983) 1448; _Ber.Bunsenges. Phys. Chem., 88 (1984) 10. 17 H. Ezzaouia, R. Heindl, R. Parsons and H. Tributsch, J. Electroanal. Chem., a (1983) 279; -165 (1984) 155. 18 R. Bichsel, F. L&y
and H. Berger, J. Phys.C&
(1984) Ll9.
19 F. Hulliger, Nature, 200 (1963) 1064. 20 R. Heindl, R. Parsons, A.M. Redon, H. Tributsch and J. Vigneron, Surf. Sci., z (1982) gl. 21W. Jaegermann, 2. Phys. Chem., 88 (1984) 5309. 22 J. Foise, K. Kim, J. Covino, K. Dwight, A. Wold, R.R. Chianelli and J. Passaretti, Inorg. Chem., 22 (1983) 61. 23 S. Svendson, Acta Chim. Stand., A33 (1979) 601. 24 Private communication,SERI, Golden COLO, 1984.
121 25 H. Ezzaouia,
R. Heindl
26 W. Jaegermann
and J. Loriers,
and H. Tributsch,
J. Mat. Sci. Lett.,
private
communication,
3 (1984) 625.
1984.
27 D.H.M.W. Thewissen, E. van der Zouwen-Assink, K. Timmer, A.H.A. Tinnemans and A. Mackor, J. Chem. Sot. Chem. Commun., 14 (1984) 941.
28 J. Ramsden, Thsse de doctorat, E.P.F.L.,
Lausanne,
1985.
29 D.H.M.W. Thewissen, A. Mackor,
A.H.A. Tinnemans, M. Eeuwhorst-Reinten, Nouv. J. Chim., 7 (1983) 191.
30 A. Onopchenko, E.T. Sabourin and C.M. Selwitz, U.S. Patent 4 216 341 (800805). communication,
U.S. Patent
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4215226 (800729);
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31 J. Cunningham,
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(1979) 2000. 33 0. Weiser and S. Landa, Sulphide Catalysts tions, Pergamon, Oxford, 1973. 34 S. Harris and R.R. Chianelli, 35 R.R. Chianelli, T.A. Pecoraro, J. Catalysis, 86 (1984) 226.
J. Catalysis, T.R. Halbert,
: Their Properties and Applica86 (1984) 400. W.-H.
Pan and E.J. Stiefel,
14 (1986)
Chemistr.v and Physics.
REVIEW
113
113 - 12 1
PAPER
CATALYSIS
AND PHOTOELECTROCHEMISTRY
ON RUTHENIUM
DISULPHIDE
SURFACES
A.J. McEVOY Ecole Polytechnique
Institut de Chimie Physique, 1015 Lausanne (Switzerland)
F&&rale
de Lausanne,
ABSTRACT
The effective catalytic behaviour of ruthenium disulphide for the hydrodesulphurisation (HDS) of organic sulphur compounds has been established. As a semiconductor electrode in a photoelectrochemical cell, the n-type material functions as a stable photoanode for oxygen evolution. As an electrocatalyst on cadmium sulphide colloids, it promotes the photochemical dissociation of H2S, and the associated evolution of hydrogen is then observed at a high rate. The present work reviews current knowledge of the catalytic and electrocatalytic behaviour of this compound.
INTRODUCTION The demands made on the catalysts stantly more severe as the industry taining
significant
amounts
current use are based kel-promoted
of sulphur
on transition
molybdeneum
in particular,
of effective
technologies
catalysts:
hydrogen,
and photoelectrochemical
catalysis
minimises
sulphides,
energy
such as Co2NiSk,
for the production trochemistry,
0254-0584/86/$3.50
supported
promoted
kinetics
(HDS)
[I,;?].
cells
for the desired
of
In electrolysis,
effects.
as cathode
electrolysis
A recent
for the production
of solar energy.
have been investigated in alkaline
RuS2
in
and nic-
for their future on the
systems
losses due to overpotential
of hydrogen
catalytically
are dependent
electrolytic conversion
cobalt-
on alumina.
disulphide,
con-
con-
The catalysts
typically
of hydrodesulphurisation
by the use of ruthenium
Two other energy-related development
sulphides
have become
'sour' crudes,
compounds.
sulphides,
for improvement
refining
increasingly
and nitrogen
metal
or tungsten
study has shown the potential catalysts,
used in petroleum processes
Transition
metal
electrocatalysts [3]. In photoelecreaction,
e.g.
0 Elsevier Sequoia/Printed in The Netherlands
114 water splitting population
otherwise
undesirable provides
to evolve hydrogen
competing
tensively
investigated
heterogenous
reduction
gies, in addition
processes,
and prospective
to the theoretical
there is at present
significant
interest
motivation
dioxide
[4] it has been ex-
colloidal
particles
in
that the ox-
[5-81. The investigation
of the
as an alternative
was therefore
applications
for
as a film on semiconduc-
itself a semiconductor,
for anodic charge transfer
With these present
interface
there is now evidence
processes
disulphide,
carrier
Since ruthenium
surface
with semiconductor
systems. However,
cathodic
of ruthenium
electrode
either deposited
or associated
photochemical
ide also promotes properties
such as photocorrosion.
oxygen evolution
as a catalyst,
surfaces,
deplete the minority
at the semiconductor/electrolyte
reactions
a very efficient
tor electrode
catalyst
available
and oxygen,
initiated
in energy-related
in clarifying
[g].
technolo-
catalytic
mechanisms
for the study of the ruthenium
di-
chalcogenides.
PHYSICAL
PROPERTIES
It has long been known that ruthenium structure
disulphide
adopts the pyrite,
[lo-121. A somewhat more recent confirmation
measurement
of the lattice parameters,
rite structure
is basically
a unit cell of edge length
C-2 type
of the structure,
was that of Sutarno
with
et al. [131. The py-
cubic (space group Pa 3) with four formula units to 5.61 8, located
Ru:
(4)
000; 0 ; $; 2 0 ;; ; ; 0.
s :
(SC)
+(uuu;
as follows:
;+u, s-u, ii; ;, ;+u, a-u; i-u, U, ;+u)
where u = 0.39 The sulphur
atoms are therefore
interpenetrating
that of the ruthenium
the pyrite structure, For ruthenium magnetic
in pairs in a F.C. cubic sublattice
atoms. By analogy with the prototype
FeS2, an oxidation
state of +2 is assigned
(d7 s') this implies a d6 ion in the crystal
properties
and associated
each filled by two electrons splitting
placed
low-spin
with opposed
from the upper, empty, d-levels
of
to the cation.
, and given its dia-
state, three low energy d-levels
spins separated
due to crystal
field
[lb]. The energy gap is therefore,
de-
fined by d-levels. The diamagnetic a preparation as prepared,
behaviour
of RuS 2, just noted,
reaction has gone to completion is normally
n-type,
ved in certain iron-ruthenium
is a convenient
[15]. The semiconducting
116-181 alth ough p-type behaviour
pyrite
width of the band gap is presently
indicator
solid solutions,
FexRul_xS2
in dispute. Originally
that
crystal,
may be obser[16]. The
a figure of 1.8 ev was
115 accepted, [lg].
based
However,
on diffuse
eV, the experimental crystals.
data being
From the relationship
from the reflectance (hv = Eg + ka2), However,
optical
reflection
derived
from reflectance
between
the absorption
data) and the photon
b) data extend only to photon
energies
below
is also inconclusive.
on this effect using
on the basis
root of quantum theless
1.8 eV is remarkably
sintered
a significant
response
[20] and was interpreted
defects
showing
of energy below
using
in the material.
with the presence
for Eg therefore
the
gap of 1.8
of some 1% of the ruthenium
a significant
of the transition
sin-
However,
followed by a higher
photoresponse
to infrared
[16,211 perhaps though an elevation
tion (hv = 1.4 eV) was obtained lence band edge associated
the square edge. None-
in terms of an energy gap of 1.3 eV
cross section,
eV. It is further noted that by substitution by iron, a semiconductor
deduced
in terms of donor levels close to the
be interpreted
with a low transition
vely by a modification
between
at the red end of the spectrum was observed
could alternatively
a
at single
this gap being
to photons
ob-
[l6,1.7]at single crystal surfaces. An even
persistent
effect
value
and they suggested
from the same laboratory,
energy near the absorption
with structural
finitive
spectra at semiconductor-elecet al. [9] made the initial
linear relationship
Fermi level and associated
(indirect)
edge
region near the previ-
RuS2 electrodes,
in later work
and the photon
spectra,
photoresponse
tered electrodes
(calculated
on.
Guittard
of an apparently
efficiency
in published
stronger
on single
:
[17] the value of 1.85 eV is accepted,
electrodes
as indirect
coefficient
and the spectral
for the energy gap from photoresponse
value of 1.3-1.5 eV. However, crystal
measurements
1.6 eV. That absorption may there-
value of 1.8 eV is not reported
interfaces
servations
Sat@eS
at a figure of 1.3
are not reported;
fore be other than the band gap effect,
Evidence
POW&red
energy close to the absorption
apply to these conclusions
a) the absolute absorption coefficients
trolyte
on
it was deduced that the band gap is indirect.
two reservations
ously reported
measurements
et al. [la] arrives
the recent work of Bichsel
of iron d electrons,
crosssection
awaits further
radia-
of the va-
or alternati-
for the indirect
experimental
sites
evidence,
gap. A dealthough
the lower value now appears more probable.
MATERIAL
PREPARATION
There is a direct
synthesis
route at high temperature
17,18,22,23] or by heating a subsulphide quartz
tube sealed under vacuum.
so the heating
of ruthenium
This reaction
must be slow and progressive.
from the elements
with sulphur
is strongly
Determination
[g,
[13] in a
exothermic
113,181
of the stoichiometry
116 of the material
so prepared
indicates
that the pyrite
tained despite
some sulphur
deficiency
phur excess is used in the synthesis,
produced
Reported
procedures
annealed,
hours
procedure
a 5% sul-
mixture
[24]. To form electrodes, may be sintered,
the
and there[20].
are either chemical vapour trans-
as transport
agent, with a 1040 - 102O'C
across the sealed quartz ampoule being maintained
or by crystallisation
at 800'C
at 1OOO'C in a sulphur atmosphere
for single crystal growth
gradient
[181;
to completion
typically
port with IC13 or an IC13-S2C12 temperature
[15,23]. At SERI, for example,
in the synthesis
after where necessary
can be main-
and the sealed tube is maintained
for three days to bring the reaction microcrystals
structure
[16,17,251
from a tellurium
for 700
or bismuth
[26l
melt. Ambient
temperature
preparation
procedures
[15] using a metathesis
reaction
RuC13 + 2(NH4)HS
RuS2 + HCl + 2NHqC1
This reaction
_I)
is generally
of the type
for RuS2 have also been reported
:
(1)
carried out in a nonaqueous
clusion of oxygen, to avoid any oxide or hydroxide the initial material
sample of RuC13 should also be anhydrous.
has been mentioned
[2] but problems
solvent,
formation
and with the ex-
[2,l5]. Equally,
Use of an 'RuC14' starting
of stability
and handling
of such a
compound may be anticipated. It must be recognised a short-range in contrast bility
of these reactions
order of the RuS2 type. The filtered precipitate
to the stability
is non-zero.
An annealing
that the product
of the pyrite RuS2 crystal.
Only a featureless
in H2S at a temperature
lise this product.
can only be obtained
to crystallise,
diffraction
after annealing
pattern
and the density
at 850'~ [15]. The structure
of ruthenium
fore be questionable;
there was for a time the suggestion
a charge-neutralised
E.S.C.A. species
studies have established
free elemental E.S.C.A. tainty).
sulphur
features,
formed by low temperature
co-colloid
(-2), and the presence
of ruthenium
the oxidation
of some sulphate
is obtainable. to stabi-
of 6.23
diamagk 0.03
and stoichio-
alone must there-
that the product was
and sulphur. However.
state of the sulphur contamination,
(due to the small chemical
its oxidation
pattern
suscepti-
but a well-defined
metry of any sulphide
merely
can be pyrophoric,
The magnetic
greater than 25O'C is necessary
At 350°C it begins
netic solid giving the pyrite
X-ray diffraction
show, at best, only
our
(dimer)
but certainly
shifts of the ruthenium
state is more difficult
to specify with cer-
no
117 One advantage sulphide
of the metathesis
deposits
cles of other semiconductors exposed
procedure
is that ruthenium
or colloidally
suspended
di-
parti-
27,28 . Here the surface or colloid is
e.g. C&3
to RuC13 or K2RuC16
ion introduced,
preparation
may also be laid on surfaces
in aqueous
solution
for example, by bubbling
, which then reacts with sulphide
H2S or as a NaHS solution.
ELECTROCHEMISTRY In the initial work with sintered gen evolution current
in darkness with a surprisingly
density
trolyte,
of 4.5 ITLO. cm
-2
trode surface was only slightly
cathodic
anodic dark current
terface.
with an essentially
In an alternative
perspective
RuS2 electrode
[16,171. While hydrogen
electrode
dark reaction
surface
Mott-Schottky tigations,
RuS2 electrodes
effects
close to the H20/02
:an be obtained
redox potential The chemical
tal electrode
beha-
more conventional
beha-
potentials
in dark-
[16,17,18I.
dependent
associated
Linear
potential
at -0.48 V
with the observed is however
state recombinatLon
a significant
of the surface
Only conis
photocurrent
has been explained
t28l.
on-
subject to
with this photocurrent
The fact that a continuous
states defining
inves-
on light intensity.
anodic potential
and photocorrosion
'd' nature of the electron
of that
potential.
in the single-crystal
a flat-band
A fur-
and the sintered
is the reduction
does it rise to represent
reaction
with surface
is very stable,
The non-ideal
hydrogen
This photoresponse
only at this relatively
of competition
to the pure
elicited
is compatible
and is not linearly
rerified as oxygen evolution
of deep donor states at
at cathodic
(l/C2 vs V) have been obtained indicated
in-
evident.
electrolytes,
of which
surface
solid-electrolyte
both on the single-crystal
(pH 1). This value
of that
The ef-
under anodic bias is no longer observed.
for anodic photoeffects.
tinous photocurrent.
the basis
is, however,
observed
the extrapolation
strong transient
but it was suppres-
of the oxidised
semiconductor.
just anodic of the reversible
(NHE) in acid electrodes set potential
in the occured
already mentioned.
[171 the charging
in oxygen-saturated
plots
potential,
ohmic contact
is still evolved
ness, the dark oxygen evolution
oxygen at potentials
the elec-
by a hysteresis
leading to a 'metallic'
may give a degenerate
Later work on single-crystal
ther cathodic
hydrogen
oxygen evolution
semiconductor,
these anodic potentials
viour
in a 0.1 M KOH elec-
The onset of an anodic photocurrent
and associated
viour of the sintered
was observed (a
sweep in the anodic sense prior to the appearance
fect may be associated with the underlying
[9,20] oxy-
Under these conditions
as evidenced
oxidised,
of the reversible
a potential
low overpotential
difference).
anodic region of the voltammogram. at a potential
RuS2 electrodes
with a Pt counterelectrode,
under a 1.5 V potential
sed during
polycrystalline
on
The single-crysis minimal,
the valence
due
and conduc-
118 tion band edges. In contrast, in the diselenide and ditelluride of ruthenium there is increasing photocorrosion,giving Ru02 and chalcogenate ion, associated with the increasing mixing of ruthenium d and chalcogen p electron states in the band structures of the compounds. For ruthenium disulphide, then, the dark hydrogen evolution, the oxygen-evolving photoeffect and the Mott-Schottky data are presented as evidence for a valence band edge close to the H20/02 redox potential, and the conduction band edge at some -0.5 V (NHE) in darkness; this would imply a band gap of 1.8 eV [l'i']. Photoelectrochemicalexperiments then show that those band edges become unpinned under illumination in the presence of an oxidisable species in aqueous solution; the potential at which a continuous photocurrent is established is displaced snodically with electrolyte redox potential over a wide range, from -0.48 V (NHE) for a sulphide electrolyte to +1.23 V (NHE) for oxygen evolution. The unpinning, and by consequence the anodic onset for photoevolution of oxygen, makes RuS2 an unfavorable candidate for energy conversion by photolysis of water: it also makes credible the narrower band gap (1.3 eV).
PHOTOCHEMICAL CATALYSIS BY RUTHENIUM DISULPHIDE Firely divided cadmium sulphide has been loaded with a ruthenium sulphide by a metathesis reaction (1) in the presence of an aqueous suspension of the CdS particles, followed by drying and annealing in a H2S atmosphere [27,281. For the photochemical dissociation of H2S in aqueous solution, this catalysed CdS suspension is some seven times more effective than Ru02-loaded material [29]. The RuS2 catalyst has the additional advantage of long-term stability. By spectral photoresponse it was confirmed that the CdS was the active semiconductor for photoexcitation, with an onset at 520 nm, hv = 2.4 eV. The function of the RuS2 as a catalyst is therely established, though it is not clear whether it influences preferentiallythe kinetics of the anodic or cathodic reaction
DESULPHURISATIONAND HYDROPROCESSINGREACTIONS These provide the most probable short-term economically significant application, and petroleum industry laboratories have been investigatingRuS2 catalysts for hydrodenitrogenation1301 HDN and hydrodesulphurisation[1,2] HDS of organic compounds for some time. For desulphurisationa systematic preparation of, and a comparison of the catalytic effiency of, a series of metal sulphides have been carried out. Model organosulphur compounds were then treated in an autoclave reactor in the presence of these test catalysts, the products being monitored by mass spectroscopy or gas chromatography.For example, the thermal desulphurisa-
119 tion of tertiary butyl thiol to yield a butene proceeds over an RuS2 catalyst to completion [311 :
(CH~)CSH
*,
(cH~)~c=CH~ + H2s
(2)
RuS2 This by analogy with the dehydration of the corresponding alcohol over a metal oxide catalyst 1321. 2oo"c ~---& 2
(CH2)3COH
(cH~)~c=cH~ + H~O
A useful reference compound for hydrodesulphurisation,HDS, is dibenzothiothene. Among the transition metal sulphides, the catalytic activity for this reaction varies by three order of magnitude. While the sulphides of the first row transition metals show a low and fairly constant activity, those of the second and third row show a significant dependence on location in the periodic table peaking sharply with the sulphides of ruthenium (2nd row) and osmium (3rd row) ('volcano curve', 1,2). During operation of the HDS reaction the ruthenium compound gradually becsme substoichiometricin sulphur. It is generally accepted that sulphur vacancies on the catalyst surface provide the reaction sites for HDS [33],
such vacancies occuring particularly easily in pyrite RuS2, where the
sulphur atoms occur in pairs. However, the interpretationof this catalytic behaviour in terms of the electronic, structural and chemical properties of the material is only now evolving [34], as is consideration of RuS2 as a model for the design of new catalysts of sulphides of base metals with enhanced activation due to selective surface alloying methods [35].
CONCLUSION Ruthenium disulphide is a promising material for the thermal catalytic processing of organic sulphur and nitrogen compounds in petroleum refining. It also has interesting photoelectrochemicalbehaviour, and photochemical catalytic properties. It is a useful model system for the study of catalytic mechanisms. Single crystals, polycrystalline samples and loaded colloids have been prepared and evaluated. However, materials improvement is still required, and characterisation of several physical and chemical parameters of RuS2 is still incomplete.
ACKNOWLEDGEMENTS Contact with Prof. Dr. H. Tributsch and Dr. A. Mackor was promoted by the European Community 'Stimulus'programme, contract STI-005-J-C (CD). Discussions
120 with Prof. J. Cunningham were useful. Prof. M. GrEtzel encouraged this present work, which is currently supported by the Swiss National Fund for Scientific Research.
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