- Email: [email protected]
Palladium-catalyzed reductive dehalogenation of dissolved chlorinated aliphatics using electrolytically-generated hydrogen
Chemosphere, Vol. 37, No. 5, pp. 925-936, 1998 0 1998 Elsevier Science Ltd All rights reserved. Printed in Great Britain 004%6535/98 $19.00+0.00
Pergamon
PII: SO0456535(98)00095-Z PALLADIUM-CATALYZED CHLORINATED ALIPI-IATICS
REDUCTIVE DEHALOGENATION OF DISSOLVED USING ELECTROLYTICALLY-GENERATED HYDROGEN
Walt W. McNab, Jr. and Roberto Ruiz
Environmental
Restoration Division, Lawrence Livermore Livermore, CA 9455 1, USA
National Laboratory
(Received in Germany 22 December 1997; accepted 27 February 1998)
Abstract Recent studies have shown that reductive dehalogenation of chlorinated hydrocarbons by hydrogen occurs rapidly in the presence of a palladium catalyst. The speed and completeness of these reactions may offer advantages for groundwater remediation. A practical design challenge arises with the need to expeditiously saturate the aqueous phase with hydrogen. To address this, a two-stage treatment column (hydrogen generator and catalytic reactor) has been developed. The first stage consists of an undivided electrolyzer cell which generates hydrogen by electrolyzing the influent water. The second stage contains a catalyst bed of palladium metal supported on alumina beads. This reactor has been tested with groundwater containing various chlorinated aliphatics. Using a flow rate of 300 ml/min and a current of 4 amps under a potential of 8 volts, removal efficiencies greater than 95% were achieved for PCE, TCE, 1,1-DCE, and carbon tetrachloride with residence times on the order of 2 minutes. Chloroform and 1,2-DCA appear less susceptible to dehalogenation by this process. These results imply that dissolved oxygen present in solution does not completely inhibit reduction of the chlorinated hydrocarbons on the catalyst. 01998
Elsev~~
Science Ltd. All rights reserved
Introduction Contamination
of groundwater
is a familiar environmental processes
(e.g., hydrolysis)
with respect
to carbon
problem.
conditions
dehalogenation
dioxide.
Most of these compounds
[ 11.
However,
because
counterparts, Reductive
has been well documented
iron can transform
hydrocarbons
(e.g., PCE, TCE, chloroform)
are resistant to non-redox
halogenated
a potential
dehalogenation
hydrocarbons
by indigenous
[2-61. More recently, the discovery
a variety of halogenated
compounds
chlorinated
using batch reactors
instability
are in an oxidized
reaction pathway exists for degradation soil microbes that zero-valent
[9] have demonstrated
state
through
under anaerobic metals such as
[7, 81 has led to the design of engineered
treatment systems, such as passive treatment walls, for purposes of groundwater Experiments
transformation
and are often difficult to oxidize despite their inherent thermodynamic
relative to their non-halogenated reductive
resources by halogenated
in
situ
plume remediation.
that hydrogen
can effectively
reduce
ethenes in the presence of a palladium catalyst, yielding ethane and HCI,
TCE + 4Hz --> ethane + 3H+ + 3Cl. 925
(Eq. 1)
926 This Hz/Pd process results in rapid, essentially intermediate
transformation
reduction
processes.
hydrocarbons
products
Similarly,
complete
such as vinyl chloride palladium-coated
iron
dissolving
sufficient
quantities
contact time presents engineering water has been evaluated stage process,
been
shown
or metal-based
to transform
chlorinated
treatment methods based on the
particularly
in treatment columns where a
implying a short residence
time.
However.
as an alternative
In this study, in-line generation
of Hz by electrolysis
of suitable electrodes
immersed
in the influent stream under
applied voltage and current to generate H’. Effluent from the first stage, containing
second
bed containing
stage, a packed
measuring
the concentration
efficiencies
chlorinated
hydrocarbons
remediation
tetrachloroethene
a palladium
hydrocarbons.
metal catalyst
of the chlorinated
were conducted
supported
hydrocarbons
Hz
is in turn passed to the on alumina
beads.
By
across the catalyst bed, removal
(PCE),
chloroform,
35
trichloroethene
indicate
carbon tetrachloride
aliphatics
east
of
San
Francisco.
I-2 dichloroethene
(TCE),
( 1,2-DCA).
time on removal efficiency
that the electrolytic-HJPd
process
Contaminants
( I, 1-DCE),
The objectives
to estimate design parameters
slower rate. whereas
with
carbon
and quantifying
impractical.
Chloroform
included
reaction rates for
operational
treatment
unit.
l,l-DCE,
and
treat PCE, TCE,
was also removed
of
tetrachloride
of the experiments
for a scaled-up
will effectively
consisted
at low flow rates where electric current demands and residence time constraints
too high so as to render the process significantly
contaminated
National Laboratory (LLNL), a Superfund site undergoing
miles
and l&dichloroethane
each of the chlorinated The results
with the test reactor using groundwater
at Lawrence Livermore
approximately
measuring the effects of current and residence
efficiency
chlorinated
dissolved
may be quantified.
A series of experiments
(CTET),
and dissolved
differences
of
to the direct injection of Hz gas. This approach involves a two-
with the first stage consisting
of electrolysis)
in such
of Hz in the intluent stream with limited space and with limited
and safety issues.
(and 02 as a byproduct
active
ethenes, whereas
are often noted in microbial has
applications,
high flow rate relative to column volume is desired.
sufficient
of the chlorinated
much more readily than iron metal alone [IO]. Groundwater
HJPd process offer promise for certain remediation
situations,
transformation
are not
by this process but at a
1,2-DCA appeared to be largely resistant altogether.
In addition, process
was observed to generally decline with time, apparently in response to surface reactions involving
the catalyst and inorganic constituents by temporarily
in the groundwater
solution.
This decline was found to be reversed
shutting off the hydrogen source.
Materials, Equipment,
and Methods
ColurnrzDesign The two stages of the treatment column are depicted in Figure 1. The electrolyzer cylindrical
graphite sheet electrodes,
PVC vessel. manner.
The electrodes,
separated
approximately
each 56 cm-long, housed within a 60 cm-long by 7.6 cm diameter clear
each supported
structurally
by an annular distance of 0.5 cm.
1300 cm?. while
unit contains two
that of the inner
by clear PVC tubing, are configured
The outer electrode electrode
in a coaxial
features a total surface area of
is approximately
I100 cm’.
Electrical
927
connections
to an external power supply unit are established
the graphite sheets. resulting
DC current is supplied by a regulated-current
in average current densities
polarity is switched with a frequency calcium carbonate) in a 40 cm-long
through 0.6 cm stainless steel pins attached to
on the electrodes
power supply.
At a current of 4 amps, the
are on the order of 3.3 milliamps/cm’.
of five minutes to prevent the accumulation
Electrode
of mineral deposits
(e.g.,
on the cathode resulting from local increases in pH. The packed catalyst bed is housed by 7.6 cm diameter
clear PVC tube.
The catalyst material consists
of alumina
spheres of a 0.32 cm nominal diameter coated with 1% palladium metal by weight (Prototech, to a porosity of approximately
(Alz03)
Inc.), packed
40%.
CATALYST
BED
‘CphW
WllC r w -
-c
FIGURE
1. Schematic
diagram of test column (not to scale).
Sampling ports are located upstream of the electrolyzer bed, and downstream
of the catalyst bed.
Stainless
cell, between the electrolyzer
and the catalyst
steel valves and tubing were used for connections
and
sampling ports.
Operation
The column was operated at a test stand within an existing groundwater Water
from an extraction
well (W-351)
used to supply contaminated
partially diverted to the test column for the experiments, geochemical
composition
and contaminant
concentrations
treatment facility at LLNL.
groundwater
to the facility
with the well water serving as the electrolyte. characterizing
was The
W-35 1 water are given on Table 1.
928 TABLE 1. Groundwater chemistry measured in W-35 1(chlorinated hydrocarbons, majo rc :ations and anions). Species Cont. (mg/l)* 0.005-0.007 PCE 0.5-0.6 TCE 0.0 150.025 l,l-DCE 0.008-0.015 Carbon tetrachloride 0.004-0.01 Chloroform 0.004-0.01 1,2-DCA 200-220 Bicarbonate alkalinity 50-95 Ca*+ 70-120 cl15-20 Mg?+ 25-30 NOs1-2 K+ 100-I 10 Naf 55-13s SOJ’~ 7.2-8.2 PH 4-5 Dissolved 02 ’ Ranges denote observed
variability
Water was pumped through a particulate ml/min using a diaphragm electrolyzer
with a mechanical
uncertainties
filter and into the electrolyzer
cell at approximately
300
No attempt was made to separate anodic and cathodic waters within the
or within the catalyst bed. A back-pressure
entire column Residence
pump.
over time, not analytical
regulator
times within the electrolyzer
minutes and 2.3 minutes, respectively;
of approximately
to suppress
the formation
2.5 atm was maintained
across the
of gas bubbles during electrolysis.
cell and catalyst bed for most experiments
was approximately
these could be adjusted by changing the flow velocity.
6
Effluent from
the catalyst bed was fed back into the main treatment facility line. A programmable
logic controller coupled with Labview control software (National Instruments,
was used to regulate experiment and electrode
current/voltage
settings, including process water flow control, electrode polarity switching,
settings.
The system was monitored
sensors placed upstream and downstream electrolyzer
Sampling
pH, flow, and pressure
For abnormal operating conditions
over voltage, loss of flow to electrolyzer,
(pump failure,
or high electrolyte
and Anu1~~se.s
were collected
reactor
to monitor
analyzed by gas chromatography 0.4
by temperature,
the system was designed to shut down using interlock controls.
Samples catalytic
of the reactors.
power supply failure, electrolyzer
temperature),
Inc.)
Kg/l or approximately
concentrations
upstream
process
of the electrolyzer
effectiveness.
in accordance
Chlorinated
hydrocarbons
and downstream in water samples
of the were
with EPA Method 601 [ 111. Detection limits were generally
0.4 parts-per-billion
of TCE, where dilution
and both upstream
requirements
(ppb)
except
in influent
raised the detection
samples
containing
limit to 4.0 ppb.
high
Likely end-
929 products
of the reductive
quantified
dehalogenation
sequence
- ethane,
by Method 601. Because of high background
not feasible
to attempt mass balance calculations
methane,
concentrations
on the reductive
and ethene
- are not effectively
of chloride in W-351 water, it was
dehalogenation
reactions
by including
chloride analysis in the experiments.
Results Changes
in contaminant
concentrations
across the column using W-351 water under 4 amps at 8
volts are shown in Figure 2(a) for TCE and Figure 2(b) for l,I-DCE flow rate of 300 ml/min.
Across the catalyst bed, chlorinated
than 95% after approximately residence
time within
and carbon tetrachloride
hydrocarbon
2 minutes of residence time. In comparison,
the electrolyzer,
losses
of only lo-15%
concentrations
(CTET) for a
declined by more
during the approximate
were observed.
probably attributable
to adsorption
of the organics onto the graphite electrodes
as well volatilization
into minute O2 and H2 gas bubbles present in the column.
6-minute
These minor losses
are
and other column materials
FIGURE 2. Removal of chlorinated aliphatics across the two-stage reactor at 8 V and 4 amps under a flow rate of 300 ml/mm. a) TCE; b) 1, I-DCE and carbon tetrachloride. Electrical Requirements The electrolysis
Thermodynamic
reactions occurring at the cathode and anode are, respectively,
(Eq. 2)
2H20 --> O2 + 4H+ + 4e-
(Eq. 3)
arguments suggest that the generation
V, based on the standard voltage potentials
2H20 + 2e- --> H2 + 20H.
potentials
of H2 should commence
for the half-reactions
at a minimum voltage of 1.2
given by Eqs. (2) and (3).
are usually required before Hz is generated because of overvoltage
In practice,
larger
effects on the electrode
930 surfaces [ 121. The minimum current required to saturate the influent stream with HZ within the electrolyzer vessel may be calculated
by the reaction stoichiometry.
100% current efficiency,
is given by:
The theoretical
rate of production
of HZ, assuming
(Eq. 4)
where RHOis the rate in moleskec, 96,500 coulombs/mole.
i the current in amperes (coulombskec),
The factor 2 arises from the stoichiometry
and F the value of the Faraday,
of Eq. (2), which indicates that one mole
of HZ is produced for each Faraday of electricity. The concentration electrolyzer
of hydrogen produced
in the column, CHZ, is a function of the molar flux in the
and the flow rate, f, in liters/set:
The solubility of HZ in water at 2.5 atm and 20°C is approximately
2.0 x 10e3 mole/l.
Thus, for a flow rate
of 300 ml/min, it may be shown that a 1.9 amp current would be required to achieve Hz saturation. Removal efficiency,
RE, is defined based on contaminant
concentration
differences
in the influent
and effluent streams,
C
RE=l-$!hK
Removal efficiency
as a function of current, measured with reference to residence within the catalyst bed, is
shown in Figure 3 for two different
residence
times.
Catalyst residence
times were calculated
the catalyst bed pore volume by the flow rate.
These results suggest a clear relationship
efficiency
efficiency
volts.
and applied current, with maximum
Although
the cell voltage is manipulated
which determines
not achieved
in the experiments,
the quantity of Hz that is generated.
by dividing
between removal
below approximately
4 amps at 8
it is primarily the electrolytic
The observed 4 amp current at maximum
current
efficiency
is higher than the ideal value of 1.9 amps required to saturate the solution with Hz. This suggests that an excess of hydrogen is required to reduce the chlorinated recombination effect.
hydrocarbons.
of Hz and 02 to form water, or the reduction
The lower-than-expected
side reaction rates.
removal efficiency
Possible side reactions involving the
of NOJ- by Hz, may be responsible
observed at 8 amps may be a reflection
for this
of increases
in
931
.
70%
E 5 I
60%
f x B E
50%
6V
16V 7 HP supersaturation
40%
B
0
1
2
4
3 current
FIGURE 3. Removal efficiency
5
7
6
6
(amps)
of TCE versus applied electric current.
Reaction Rates The relationship TCE with current
between
removal efficiency
equal to or greater than 4 amps (applied
Previous workers [9] had used a first-order process
assuming
a constant HZ concentration
order degradation
consistently
Estimated
observed
effective
Nevertheless,
that of chloroform
of a first-
in the test column yielded a mean effective
0.02 sec.‘, corresponding reaction
rates
to a reaction
for the other
chlorinated
first-
half-life
of
aliphatics
(PCE, TCE, and I,l-DCE)
and carbon tetrachloride
is less than these by a factor of at least two. The transformation
observed
across the two-stage
reductive dehalogenation
In all of the experiments
reactor due to mechanisms
conducted,
as well as carbon tetrachloride
water, the production
The
are very similar, while of 1,2-DCA appears to
Given the small losses (lo-15%) other than reductive
dehalogenation,
of 1,2-DCA is suspect.
methyl chloride) were not observed
TCE, l,l-DCE
and other factors.
the relative rates of reaction of the different compounds.
be very slow, with a rate less than l/20 of that of the chloroethenes.
chloride,
Application
02, packing of the catalyst, mixing processes,
they are useful for comparing
rates for the three chloroethenes
significant
by the H$Pd
present in W-351 water are shown on Table 2. Such rates are specific to these experiments
since they reflect the influence of dissolved
typically
greater than or equal to 8 volts).
and a constant catalyst surface area.
rate for TCE of approximately
30 seconds.
potential
time is shown in Figure 4 for
kinetic model to describe reductive dehalogenation
order kinetic model to the removal efficiencies
approximately
and catalyst residence
unequivocal
chlorinated
above applicable detection and chloroform
of some transient chlorinated
intermediates
degradation limits.
products
However,
given that PCE,
are all present as co-contaminants cannot be completely
(e.g., vinyl
ruled out.
in W-351
932
y=eQmr R2= 0.73
FIGURE 4. Removal efficiency amps or higher).
versus catalyst residence time (at 8 V and 4
TABLE 2. Estimated first-order reaction coefficients for chlorinated aliphatics in catalyst bed (4 amps current at 8 volts, l/S-inch (0.32 cm) diameter A1203 spheres coated with 1% Pd by weight). Species Rate constant (set”)’ PCE 20.02 TCE 0.02 1 + 0.005 l,l-DCE 0.019 + 0.002 Carbon tetrachloride 20.02 Chloroform SO.009 1,2-DCA <0.0009
’High analytical detection limits relative to concentrations of PCE, carbon tetrachloride, chloroform, and I ,2-DCA precluded more precise estimates. When given, errors refer to standard deviations. Effect of Dissolved Oxygen In addition to reductive dehalogenation, on the catalyst is the recombination
a competing
hydrogen-consuming
reaction which may occur
of Hz and 02, either in the aqueous or gaseous phase,
O2 + 2H, --> 2H20
(Eq. 7)
This reaction is known to occur vigorously in the presence of platinum [ 131. The solubility of 02 in water at 20°C and 0.5 atm (2.5 atm pressure x 20% mole fraction in air) is approximately concentration
is almost
certainly
background
concentrations
comparison,
the mean concentration
reached
of dissolved
as the influent
passes
through
6.9 x 1O-4mole/l.
the electrolyzer,
given
02 in W-351 water are already greater than 3 x IO-’ mole/l.
of TCE, the most abundant chlorinated
hydrocarbon
This that In
in W-35 1 water, is
933 approximately equivalent
3.8 x 1O-6mole/l.
to the reductive
greatly suppressed
reaction
this issue, an experiment
porous polypropylene
membrane
and cathodic electrolyzer
observed
dehalogenation
reaction given by Eq. (7) were to proceed given by Eq. (1) reductive
at a rate
dehalogenation
would be
or not occur at all.
To address
the anodic
If the recombination
stream,
column
dehalogenation,
catalyst surface to some degree.
design
mixing of the anodic
This action appeared
suggesting
Nevertheless,
to approximately
that 02 does compete
practical engineering
considerations
preclude modifying
Separation of the two electrolytic
a divided-cell
would add complexity
create locally extreme
(i.e. separate anolyte and catholyte)
double
the
with TCE for HZ on the
design of a full-scale reactor to take advantage of this finding. arrangement
in which a
The cathodic stream, enriched in Hz, was fed into the catalyst bed, while
in 02, was discarded.
rates of reductive
with a modified
was placed within the cell to suppress mechanical
streams.
enriched
was conducted
the
streams in
to the design, would
pH values, and would fail to address the issue of remediating
the Hz-poor anodic
water.
Choice of Electrode Material The choice of suitable requirement
to periodically
graphite performed
electrode
switch
adequately
scale unit.
Unfortunately,
the platinum address
Consequently,
identifying
The precious
inhibits the conduction
to prevent
operational
CaCOs precipitation
unit is complicated on the cathode.
Although
showed considerable
replacement
iridium, ruthenium)
metal coating prevents
wear over
would be required in a full-
Titanium metal coated with a member of
is often used in electrolytic the formation
applications
To assess suitability
than using
of one such material in the
treatment column, the graphite electrodes
were replaced with two titanium cylinders of equivalent
each coated on both sides with ruthenium
oxide (obtained from The Electrosynthesis
conducted
twice
concentrations
declining
phenomenon
as the graphite)
indicated
by only about 40% across the catalyst
is that the ruthenium
HzO, depleting dehalogenation.
as conductive
titanium rod which was employed
removal
bed.
to the Pd catalyst
A possible
was tested by replacing
bed, thus reducing
the innermost
as a cathode under a fixed polarity.
proved to be
efficiencies,
with TCE
explanation
oxide surface acts as a catalyst for the recombination
the HZ in the influent This hypothesis
poor
geometry,
Co., Inc.). Initial tests,
with a flow rate of 300 ml/min under 4.1 volts and 4 amps (the Ti-RuOz electrodes
approximately
to
of a TiOx oxide layer which
Using titanium as a base material is less expensive
metal components.
by the
for graphite is difficult because most metals
when used as an anode.
of an electric current.
made entirely of precious
frequent electrode
a suitable replacement
or passivation
metal group (e.g., platinum,
this problem.
electrodes
polarity
in a full-scale
in the pilot tests in this study, the electrodes
the course of the experiments.
tend to undergo corrosion
materials
for this
of 02 and Hz into
the rate of reductive
Ti-RuOz electrode
A porous polypropylene
with a pure membrane
was placed between the anode and the cathode to separate the two waters, with both streams fed into the Pd
934 catalyst bed. The resulting marked improvement
in the removal efficiency
of TCE, up to 8 l%, suggests that
the reaction of 02 and Hz on the ruthenium oxide surface is a likely cause of reduced performance. No convincing the ruthenium-oxide palladium
evidence of reductive dehalogenation coated
and ruthenium
processes.
electrodes.
within the electrolyzer
Thus, it appears
that the two precious
oxide, differ markedly in their catalytic properties
Hz reacts more readily with the chlorinated
itself was observed with
hydrocarbons
metal-based
in application
materials,
in this treatment
than with oxygen
on palladium,
whereas the opposite appears to hold true for ruthenium oxide.
Process De-Activation Influent and effluent TCE concentrations
associated
with the two-stage
reactor over an extended test
period with W-351 water are shown on Figure 5. Although the initial removal efficiency concentrations involving
rise over a period
direct injection
phenomenon, recovers
steadily
of many hours.
of Hz, rather than electrolytic
Similar
generation,
experiments
is high, effluent
conducted
have exhibited
elsewhere
the same deactivation
which apparently involves the Pd/A1203 catalyst itself [ 141. Tests have shown that the catalyst
most or all of its capacity if soaked in deionized
water over a period of hours to days. and may
recover a portion of its capacity if the hydrogen source is simply taken off line for a period of time. The rate of deactivation exacerbate
also appears to depend on water composition;
soaking of the catalyst in deionized
catalyst is not allowed to deactivate extensively addressed,
of bicarbonate
appear to
the problem.
The precise cause of the deactivation periodic
high concentrations
application
phenomenon
is currently
under investigation.
water appears to restore effectiveness, (i.e. below 50%).
particularly
Until the cause is identified
of this may require the design of a regeneration
Nevertheless. when the
and suitably
system based upon periodic deionized
water flushes.
FIGURE 5. Extended performance test of treatment column in W-35 1 water, showing both deactivation and regeneration of catalytic activity.
935 Removal
efficiency
results and rate calculations
time data in each experiment
Discussion
presented
using only fresh or regenerated
in this study were all taken from early
catalyst.
and Summary
Rapid reductive dehalogenation flow-through
treatment reactor consisting
and a packed bed of Pd/AlzOs catalyst. transformation somewhat
of dissolved
with pseudo-first-order
more slowly,
tetrachloride.
contaminated
of an electrolyzer
has been demonstrated
rate approximately
which hold implications
for the full-scale
all appear to undergo
Carbon tetrachloride
half that of the chloroethenes
Reaction products
reacts
and carbon
were not observed.
application
with a
of hydrogen from water
and carbon tetrachloride
reaction rates on the order of 0.02 sec.‘.
with a reaction
groundwater
hydrocarbons
cell for the generation
PCE, TCE, l,l-DCE,
1,2-DCA reacts very slowly, if at all.
other observations
chlorinated
A number of
of this approach
for treating
include:
(1) Reaction rates are lowered by the presence of oxygen, but the effect on process efficiency
is not severe.
(2) The Pd catalyst is subject to a deactivation
but appears to
be related to water composition. deionized
mechanism
This de-activation
which is not yet well-understood
may be reversed by periodically
water.
(3) Electrode
materials
which include
certain platinum
group metals (ruthenium)
choices for use in this process as they tend to catalyze the recombination thus removing
the reducing agent from the reductive dehalogenation
Acknowledgments. Research
soaking the catalyst in
(LDRD) grant from Lawrence
Ken Carroll, Dwayne Coufal, Scott Kawaguchi, were instrumental and the choice
of oxygen and hydrogen into water,
reaction.
This work has been funded through a U.S. Department
and Development
materials.
Livermore
of Energy Laboratory-Directed
National Laboratory.
The efforts of
Steve Orloff, Leon Newton, Stan Rudolf, and Ken Williams
in carrying out the experiments. of electrode
may be inappropriate
Jack Harrar provided
advice on electrochemical
We also wish to thank Jack Harrar, Ken Jackson,
issues
and Martin
Reinhard for their helpful reviews of the manuscript.
References 1. M. Hudlicky, Reductions in Organic Chemistry, pp. 62-67, 181. Halstead Press, New York (1984). 2. E.J. Bouwer, B.E. Rittmann, organic compounds,
and P.L. McCarty, Anaerobic
Environmental
degradation
Science and Technology 15,596-599
of halogenated (1981).
l- and 2-carbon
936 3. M. Reinhard,
N.L. Goodman,
and J.F. Barker, Occurrence
and distribution
of organic chemicals
in two
landfill leachate plumes, El~virnnnlenral Science and Technology 18, 953-961 (1984). 4. G. Barrio-Lage,
F.Z. Parsons, R.S. Nassar, and P.A. Lorenzo, Sequential
dehalogenation
of chlorinated
ethenes, Environmentczl Science and Technology 20, 96-99 (1986). 5. T.M. Vogel,
C.S. Criddle,
Environmental
and P.L. McCarty.
Transformations
Science und Technology 21,722-136
6. P.L. McCarty, Biotic and abiotic transformations Natural Attenuation
of Chlorinated
of halogenated
aliphatic
(1987).
of chlorinated
solvents in ground water, Symposium on
in Ground Wuter, EPAl54Q/R-961509.
Orgunics
compounds,
pp 5-9, Dallas,
Texas ( 1996). 7. R.W. Gillhan, and S.F. O’Hannesin, Ground Water 32,958-967 8. T.L. Johnson.
Enhanced
degradation
of halogenated
M.M. Scherer, and P.G. Tratnyek, Kinetics of halogenated
for the treatment of contaminated
10. L.Y. Liang, N. Korte, J.D. Goodlaxson. during
organic compound
degradation
Science and Technology 30, 2634-2640 ( 1996).
9. C.G. Schreier, and M. Reinhard, Catalytic hydrodehalogenation
formation
iron,
(1994).
by iron metal, Environmental
and hydrogen
aliphatics by zero-valent
the reduction
of chlorinated
ethylenes
using palladium
water, Chemosphere 31. 3475-3487 (1995).
J. C. Clausen,
of TCE by zero-valence
Q. Fernando,
and R. Muftikian,
iron and palladized
Byproduct
iron, Ground
Water
Monitoring und Review 17, 122- 127 ( 1997).
11. U.S. Environmental pollutants:
Protection
Agency, Guidelines
for establishing
40 CFR 104.1, Part 136, U.S. Government
12. CA. Hampel,
Encyclopedia
of Electrochemistry,
test procedures
Printing Office, Washington,
pp. 869-877. Reinhold
for the analyses of D.C. (1986).
Publishing
Corporation,
New
York ( 1964). 13. CRC Handbook
of Chemistry and Physics, D.R. Lide (ed.), p. 4-21. CRC Press, Boca Raton, Florida
(1992). 14. N. Munakata, catalyzed
W. McNab, W. Haag, P.V. Roberts,
hydrodehalogenation,
American
Preprints of Papers, Vol. 37, p 168 (1997).
Chemical
and M. Reinhard, Society
Division
Effects of water matrix on Pdof‘ Environment&
Chemistry,
Pergamon
PII: SO0456535(98)00095-Z PALLADIUM-CATALYZED CHLORINATED ALIPI-IATICS
REDUCTIVE DEHALOGENATION OF DISSOLVED USING ELECTROLYTICALLY-GENERATED HYDROGEN
Walt W. McNab, Jr. and Roberto Ruiz
Environmental
Restoration Division, Lawrence Livermore Livermore, CA 9455 1, USA
National Laboratory
(Received in Germany 22 December 1997; accepted 27 February 1998)
Abstract Recent studies have shown that reductive dehalogenation of chlorinated hydrocarbons by hydrogen occurs rapidly in the presence of a palladium catalyst. The speed and completeness of these reactions may offer advantages for groundwater remediation. A practical design challenge arises with the need to expeditiously saturate the aqueous phase with hydrogen. To address this, a two-stage treatment column (hydrogen generator and catalytic reactor) has been developed. The first stage consists of an undivided electrolyzer cell which generates hydrogen by electrolyzing the influent water. The second stage contains a catalyst bed of palladium metal supported on alumina beads. This reactor has been tested with groundwater containing various chlorinated aliphatics. Using a flow rate of 300 ml/min and a current of 4 amps under a potential of 8 volts, removal efficiencies greater than 95% were achieved for PCE, TCE, 1,1-DCE, and carbon tetrachloride with residence times on the order of 2 minutes. Chloroform and 1,2-DCA appear less susceptible to dehalogenation by this process. These results imply that dissolved oxygen present in solution does not completely inhibit reduction of the chlorinated hydrocarbons on the catalyst. 01998
Elsev~~
Science Ltd. All rights reserved
Introduction Contamination
of groundwater
is a familiar environmental processes
(e.g., hydrolysis)
with respect
to carbon
problem.
conditions
dehalogenation
dioxide.
Most of these compounds
[ 11.
However,
because
counterparts, Reductive
has been well documented
iron can transform
hydrocarbons
(e.g., PCE, TCE, chloroform)
are resistant to non-redox
halogenated
a potential
dehalogenation
hydrocarbons
by indigenous
[2-61. More recently, the discovery
a variety of halogenated
compounds
chlorinated
using batch reactors
instability
are in an oxidized
reaction pathway exists for degradation soil microbes that zero-valent
[9] have demonstrated
state
through
under anaerobic metals such as
[7, 81 has led to the design of engineered
treatment systems, such as passive treatment walls, for purposes of groundwater Experiments
transformation
and are often difficult to oxidize despite their inherent thermodynamic
relative to their non-halogenated reductive
resources by halogenated
in
situ
plume remediation.
that hydrogen
can effectively
reduce
ethenes in the presence of a palladium catalyst, yielding ethane and HCI,
TCE + 4Hz --> ethane + 3H+ + 3Cl. 925
(Eq. 1)
926 This Hz/Pd process results in rapid, essentially intermediate
transformation
reduction
processes.
hydrocarbons
products
Similarly,
complete
such as vinyl chloride palladium-coated
iron
dissolving
sufficient
quantities
contact time presents engineering water has been evaluated stage process,
been
shown
or metal-based
to transform
chlorinated
treatment methods based on the
particularly
in treatment columns where a
implying a short residence
time.
However.
as an alternative
In this study, in-line generation
of Hz by electrolysis
of suitable electrodes
immersed
in the influent stream under
applied voltage and current to generate H’. Effluent from the first stage, containing
second
bed containing
stage, a packed
measuring
the concentration
efficiencies
chlorinated
hydrocarbons
remediation
tetrachloroethene
a palladium
hydrocarbons.
metal catalyst
of the chlorinated
were conducted
supported
hydrocarbons
Hz
is in turn passed to the on alumina
beads.
By
across the catalyst bed, removal
(PCE),
chloroform,
35
trichloroethene
indicate
carbon tetrachloride
aliphatics
east
of
San
Francisco.
I-2 dichloroethene
(TCE),
( 1,2-DCA).
time on removal efficiency
that the electrolytic-HJPd
process
Contaminants
( I, 1-DCE),
The objectives
to estimate design parameters
slower rate. whereas
with
carbon
and quantifying
impractical.
Chloroform
included
reaction rates for
operational
treatment
unit.
l,l-DCE,
and
treat PCE, TCE,
was also removed
of
tetrachloride
of the experiments
for a scaled-up
will effectively
consisted
at low flow rates where electric current demands and residence time constraints
too high so as to render the process significantly
contaminated
National Laboratory (LLNL), a Superfund site undergoing
miles
and l&dichloroethane
each of the chlorinated The results
with the test reactor using groundwater
at Lawrence Livermore
approximately
measuring the effects of current and residence
efficiency
chlorinated
dissolved
may be quantified.
A series of experiments
(CTET),
and dissolved
differences
of
to the direct injection of Hz gas. This approach involves a two-
with the first stage consisting
of electrolysis)
in such
of Hz in the intluent stream with limited space and with limited
and safety issues.
(and 02 as a byproduct
active
ethenes, whereas
are often noted in microbial has
applications,
high flow rate relative to column volume is desired.
sufficient
of the chlorinated
much more readily than iron metal alone [IO]. Groundwater
HJPd process offer promise for certain remediation
situations,
transformation
are not
by this process but at a
1,2-DCA appeared to be largely resistant altogether.
In addition, process
was observed to generally decline with time, apparently in response to surface reactions involving
the catalyst and inorganic constituents by temporarily
in the groundwater
solution.
This decline was found to be reversed
shutting off the hydrogen source.
Materials, Equipment,
and Methods
ColurnrzDesign The two stages of the treatment column are depicted in Figure 1. The electrolyzer cylindrical
graphite sheet electrodes,
PVC vessel. manner.
The electrodes,
separated
approximately
each 56 cm-long, housed within a 60 cm-long by 7.6 cm diameter clear
each supported
structurally
by an annular distance of 0.5 cm.
1300 cm?. while
unit contains two
that of the inner
by clear PVC tubing, are configured
The outer electrode electrode
in a coaxial
features a total surface area of
is approximately
I100 cm’.
Electrical
927
connections
to an external power supply unit are established
the graphite sheets. resulting
DC current is supplied by a regulated-current
in average current densities
polarity is switched with a frequency calcium carbonate) in a 40 cm-long
through 0.6 cm stainless steel pins attached to
on the electrodes
power supply.
At a current of 4 amps, the
are on the order of 3.3 milliamps/cm’.
of five minutes to prevent the accumulation
Electrode
of mineral deposits
(e.g.,
on the cathode resulting from local increases in pH. The packed catalyst bed is housed by 7.6 cm diameter
clear PVC tube.
The catalyst material consists
of alumina
spheres of a 0.32 cm nominal diameter coated with 1% palladium metal by weight (Prototech, to a porosity of approximately
(Alz03)
Inc.), packed
40%.
CATALYST
BED
‘CphW
WllC r w -
-c
FIGURE
1. Schematic
diagram of test column (not to scale).
Sampling ports are located upstream of the electrolyzer bed, and downstream
of the catalyst bed.
Stainless
cell, between the electrolyzer
and the catalyst
steel valves and tubing were used for connections
and
sampling ports.
Operation
The column was operated at a test stand within an existing groundwater Water
from an extraction
well (W-351)
used to supply contaminated
partially diverted to the test column for the experiments, geochemical
composition
and contaminant
concentrations
treatment facility at LLNL.
groundwater
to the facility
with the well water serving as the electrolyte. characterizing
was The
W-35 1 water are given on Table 1.
928 TABLE 1. Groundwater chemistry measured in W-35 1(chlorinated hydrocarbons, majo rc :ations and anions). Species Cont. (mg/l)* 0.005-0.007 PCE 0.5-0.6 TCE 0.0 150.025 l,l-DCE 0.008-0.015 Carbon tetrachloride 0.004-0.01 Chloroform 0.004-0.01 1,2-DCA 200-220 Bicarbonate alkalinity 50-95 Ca*+ 70-120 cl15-20 Mg?+ 25-30 NOs1-2 K+ 100-I 10 Naf 55-13s SOJ’~ 7.2-8.2 PH 4-5 Dissolved 02 ’ Ranges denote observed
variability
Water was pumped through a particulate ml/min using a diaphragm electrolyzer
with a mechanical
uncertainties
filter and into the electrolyzer
cell at approximately
300
No attempt was made to separate anodic and cathodic waters within the
or within the catalyst bed. A back-pressure
entire column Residence
pump.
over time, not analytical
regulator
times within the electrolyzer
minutes and 2.3 minutes, respectively;
of approximately
to suppress
the formation
2.5 atm was maintained
across the
of gas bubbles during electrolysis.
cell and catalyst bed for most experiments
was approximately
these could be adjusted by changing the flow velocity.
6
Effluent from
the catalyst bed was fed back into the main treatment facility line. A programmable
logic controller coupled with Labview control software (National Instruments,
was used to regulate experiment and electrode
current/voltage
settings, including process water flow control, electrode polarity switching,
settings.
The system was monitored
sensors placed upstream and downstream electrolyzer
Sampling
pH, flow, and pressure
For abnormal operating conditions
over voltage, loss of flow to electrolyzer,
(pump failure,
or high electrolyte
and Anu1~~se.s
were collected
reactor
to monitor
analyzed by gas chromatography 0.4
by temperature,
the system was designed to shut down using interlock controls.
Samples catalytic
of the reactors.
power supply failure, electrolyzer
temperature),
Inc.)
Kg/l or approximately
concentrations
upstream
process
of the electrolyzer
effectiveness.
in accordance
Chlorinated
hydrocarbons
and downstream in water samples
of the were
with EPA Method 601 [ 111. Detection limits were generally
0.4 parts-per-billion
of TCE, where dilution
and both upstream
requirements
(ppb)
except
in influent
raised the detection
samples
containing
limit to 4.0 ppb.
high
Likely end-
929 products
of the reductive
quantified
dehalogenation
sequence
- ethane,
by Method 601. Because of high background
not feasible
to attempt mass balance calculations
methane,
concentrations
on the reductive
and ethene
- are not effectively
of chloride in W-351 water, it was
dehalogenation
reactions
by including
chloride analysis in the experiments.
Results Changes
in contaminant
concentrations
across the column using W-351 water under 4 amps at 8
volts are shown in Figure 2(a) for TCE and Figure 2(b) for l,I-DCE flow rate of 300 ml/min.
Across the catalyst bed, chlorinated
than 95% after approximately residence
time within
and carbon tetrachloride
hydrocarbon
2 minutes of residence time. In comparison,
the electrolyzer,
losses
of only lo-15%
concentrations
(CTET) for a
declined by more
during the approximate
were observed.
probably attributable
to adsorption
of the organics onto the graphite electrodes
as well volatilization
into minute O2 and H2 gas bubbles present in the column.
6-minute
These minor losses
are
and other column materials
FIGURE 2. Removal of chlorinated aliphatics across the two-stage reactor at 8 V and 4 amps under a flow rate of 300 ml/mm. a) TCE; b) 1, I-DCE and carbon tetrachloride. Electrical Requirements The electrolysis
Thermodynamic
reactions occurring at the cathode and anode are, respectively,
(Eq. 2)
2H20 --> O2 + 4H+ + 4e-
(Eq. 3)
arguments suggest that the generation
V, based on the standard voltage potentials
2H20 + 2e- --> H2 + 20H.
potentials
of H2 should commence
for the half-reactions
at a minimum voltage of 1.2
given by Eqs. (2) and (3).
are usually required before Hz is generated because of overvoltage
In practice,
larger
effects on the electrode
930 surfaces [ 121. The minimum current required to saturate the influent stream with HZ within the electrolyzer vessel may be calculated
by the reaction stoichiometry.
100% current efficiency,
is given by:
The theoretical
rate of production
of HZ, assuming
(Eq. 4)
where RHOis the rate in moleskec, 96,500 coulombs/mole.
i the current in amperes (coulombskec),
The factor 2 arises from the stoichiometry
and F the value of the Faraday,
of Eq. (2), which indicates that one mole
of HZ is produced for each Faraday of electricity. The concentration electrolyzer
of hydrogen produced
in the column, CHZ, is a function of the molar flux in the
and the flow rate, f, in liters/set:
The solubility of HZ in water at 2.5 atm and 20°C is approximately
2.0 x 10e3 mole/l.
Thus, for a flow rate
of 300 ml/min, it may be shown that a 1.9 amp current would be required to achieve Hz saturation. Removal efficiency,
RE, is defined based on contaminant
concentration
differences
in the influent
and effluent streams,
C
RE=l-$!hK
Removal efficiency
as a function of current, measured with reference to residence within the catalyst bed, is
shown in Figure 3 for two different
residence
times.
Catalyst residence
times were calculated
the catalyst bed pore volume by the flow rate.
These results suggest a clear relationship
efficiency
efficiency
volts.
and applied current, with maximum
Although
the cell voltage is manipulated
which determines
not achieved
in the experiments,
the quantity of Hz that is generated.
by dividing
between removal
below approximately
4 amps at 8
it is primarily the electrolytic
The observed 4 amp current at maximum
current
efficiency
is higher than the ideal value of 1.9 amps required to saturate the solution with Hz. This suggests that an excess of hydrogen is required to reduce the chlorinated recombination effect.
hydrocarbons.
of Hz and 02 to form water, or the reduction
The lower-than-expected
side reaction rates.
removal efficiency
Possible side reactions involving the
of NOJ- by Hz, may be responsible
observed at 8 amps may be a reflection
for this
of increases
in
931
.
70%
E 5 I
60%
f x B E
50%
6V
16V 7 HP supersaturation
40%
B
0
1
2
4
3 current
FIGURE 3. Removal efficiency
5
7
6
6
(amps)
of TCE versus applied electric current.
Reaction Rates The relationship TCE with current
between
removal efficiency
equal to or greater than 4 amps (applied
Previous workers [9] had used a first-order process
assuming
a constant HZ concentration
order degradation
consistently
Estimated
observed
effective
Nevertheless,
that of chloroform
of a first-
in the test column yielded a mean effective
0.02 sec.‘, corresponding reaction
rates
to a reaction
for the other
chlorinated
first-
half-life
of
aliphatics
(PCE, TCE, and I,l-DCE)
and carbon tetrachloride
is less than these by a factor of at least two. The transformation
observed
across the two-stage
reductive dehalogenation
In all of the experiments
reactor due to mechanisms
conducted,
as well as carbon tetrachloride
water, the production
The
are very similar, while of 1,2-DCA appears to
Given the small losses (lo-15%) other than reductive
dehalogenation,
of 1,2-DCA is suspect.
methyl chloride) were not observed
TCE, l,l-DCE
and other factors.
the relative rates of reaction of the different compounds.
be very slow, with a rate less than l/20 of that of the chloroethenes.
chloride,
Application
02, packing of the catalyst, mixing processes,
they are useful for comparing
rates for the three chloroethenes
significant
by the H$Pd
present in W-351 water are shown on Table 2. Such rates are specific to these experiments
since they reflect the influence of dissolved
typically
greater than or equal to 8 volts).
and a constant catalyst surface area.
rate for TCE of approximately
30 seconds.
potential
time is shown in Figure 4 for
kinetic model to describe reductive dehalogenation
order kinetic model to the removal efficiencies
approximately
and catalyst residence
unequivocal
chlorinated
above applicable detection and chloroform
of some transient chlorinated
intermediates
degradation limits.
products
However,
given that PCE,
are all present as co-contaminants cannot be completely
(e.g., vinyl
ruled out.
in W-351
932
y=eQmr R2= 0.73
FIGURE 4. Removal efficiency amps or higher).
versus catalyst residence time (at 8 V and 4
TABLE 2. Estimated first-order reaction coefficients for chlorinated aliphatics in catalyst bed (4 amps current at 8 volts, l/S-inch (0.32 cm) diameter A1203 spheres coated with 1% Pd by weight). Species Rate constant (set”)’ PCE 20.02 TCE 0.02 1 + 0.005 l,l-DCE 0.019 + 0.002 Carbon tetrachloride 20.02 Chloroform SO.009 1,2-DCA <0.0009
’High analytical detection limits relative to concentrations of PCE, carbon tetrachloride, chloroform, and I ,2-DCA precluded more precise estimates. When given, errors refer to standard deviations. Effect of Dissolved Oxygen In addition to reductive dehalogenation, on the catalyst is the recombination
a competing
hydrogen-consuming
reaction which may occur
of Hz and 02, either in the aqueous or gaseous phase,
O2 + 2H, --> 2H20
(Eq. 7)
This reaction is known to occur vigorously in the presence of platinum [ 131. The solubility of 02 in water at 20°C and 0.5 atm (2.5 atm pressure x 20% mole fraction in air) is approximately concentration
is almost
certainly
background
concentrations
comparison,
the mean concentration
reached
of dissolved
as the influent
passes
through
6.9 x 1O-4mole/l.
the electrolyzer,
given
02 in W-351 water are already greater than 3 x IO-’ mole/l.
of TCE, the most abundant chlorinated
hydrocarbon
This that In
in W-35 1 water, is
933 approximately equivalent
3.8 x 1O-6mole/l.
to the reductive
greatly suppressed
reaction
this issue, an experiment
porous polypropylene
membrane
and cathodic electrolyzer
observed
dehalogenation
reaction given by Eq. (7) were to proceed given by Eq. (1) reductive
at a rate
dehalogenation
would be
or not occur at all.
To address
the anodic
If the recombination
stream,
column
dehalogenation,
catalyst surface to some degree.
design
mixing of the anodic
This action appeared
suggesting
Nevertheless,
to approximately
that 02 does compete
practical engineering
considerations
preclude modifying
Separation of the two electrolytic
a divided-cell
would add complexity
create locally extreme
(i.e. separate anolyte and catholyte)
double
the
with TCE for HZ on the
design of a full-scale reactor to take advantage of this finding. arrangement
in which a
The cathodic stream, enriched in Hz, was fed into the catalyst bed, while
in 02, was discarded.
rates of reductive
with a modified
was placed within the cell to suppress mechanical
streams.
enriched
was conducted
the
streams in
to the design, would
pH values, and would fail to address the issue of remediating
the Hz-poor anodic
water.
Choice of Electrode Material The choice of suitable requirement
to periodically
graphite performed
electrode
switch
adequately
scale unit.
Unfortunately,
the platinum address
Consequently,
identifying
The precious
inhibits the conduction
to prevent
operational
CaCOs precipitation
unit is complicated on the cathode.
Although
showed considerable
replacement
iridium, ruthenium)
metal coating prevents
wear over
would be required in a full-
Titanium metal coated with a member of
is often used in electrolytic the formation
applications
To assess suitability
than using
of one such material in the
treatment column, the graphite electrodes
were replaced with two titanium cylinders of equivalent
each coated on both sides with ruthenium
oxide (obtained from The Electrosynthesis
conducted
twice
concentrations
declining
phenomenon
as the graphite)
indicated
by only about 40% across the catalyst
is that the ruthenium
HzO, depleting dehalogenation.
as conductive
titanium rod which was employed
removal
bed.
to the Pd catalyst
A possible
was tested by replacing
bed, thus reducing
the innermost
as a cathode under a fixed polarity.
proved to be
efficiencies,
with TCE
explanation
oxide surface acts as a catalyst for the recombination
the HZ in the influent This hypothesis
poor
geometry,
Co., Inc.). Initial tests,
with a flow rate of 300 ml/min under 4.1 volts and 4 amps (the Ti-RuOz electrodes
approximately
to
of a TiOx oxide layer which
Using titanium as a base material is less expensive
metal components.
by the
for graphite is difficult because most metals
when used as an anode.
of an electric current.
made entirely of precious
frequent electrode
a suitable replacement
or passivation
metal group (e.g., platinum,
this problem.
electrodes
polarity
in a full-scale
in the pilot tests in this study, the electrodes
the course of the experiments.
tend to undergo corrosion
materials
for this
of 02 and Hz into
the rate of reductive
Ti-RuOz electrode
A porous polypropylene
with a pure membrane
was placed between the anode and the cathode to separate the two waters, with both streams fed into the Pd
934 catalyst bed. The resulting marked improvement
in the removal efficiency
of TCE, up to 8 l%, suggests that
the reaction of 02 and Hz on the ruthenium oxide surface is a likely cause of reduced performance. No convincing the ruthenium-oxide palladium
evidence of reductive dehalogenation coated
and ruthenium
processes.
electrodes.
within the electrolyzer
Thus, it appears
that the two precious
oxide, differ markedly in their catalytic properties
Hz reacts more readily with the chlorinated
itself was observed with
hydrocarbons
metal-based
in application
materials,
in this treatment
than with oxygen
on palladium,
whereas the opposite appears to hold true for ruthenium oxide.
Process De-Activation Influent and effluent TCE concentrations
associated
with the two-stage
reactor over an extended test
period with W-351 water are shown on Figure 5. Although the initial removal efficiency concentrations involving
rise over a period
direct injection
phenomenon, recovers
steadily
of many hours.
of Hz, rather than electrolytic
Similar
generation,
experiments
is high, effluent
conducted
have exhibited
elsewhere
the same deactivation
which apparently involves the Pd/A1203 catalyst itself [ 141. Tests have shown that the catalyst
most or all of its capacity if soaked in deionized
water over a period of hours to days. and may
recover a portion of its capacity if the hydrogen source is simply taken off line for a period of time. The rate of deactivation exacerbate
also appears to depend on water composition;
soaking of the catalyst in deionized
catalyst is not allowed to deactivate extensively addressed,
of bicarbonate
appear to
the problem.
The precise cause of the deactivation periodic
high concentrations
application
phenomenon
is currently
under investigation.
water appears to restore effectiveness, (i.e. below 50%).
particularly
Until the cause is identified
of this may require the design of a regeneration
Nevertheless. when the
and suitably
system based upon periodic deionized
water flushes.
FIGURE 5. Extended performance test of treatment column in W-35 1 water, showing both deactivation and regeneration of catalytic activity.
935 Removal
efficiency
results and rate calculations
time data in each experiment
Discussion
presented
using only fresh or regenerated
in this study were all taken from early
catalyst.
and Summary
Rapid reductive dehalogenation flow-through
treatment reactor consisting
and a packed bed of Pd/AlzOs catalyst. transformation somewhat
of dissolved
with pseudo-first-order
more slowly,
tetrachloride.
contaminated
of an electrolyzer
has been demonstrated
rate approximately
which hold implications
for the full-scale
all appear to undergo
Carbon tetrachloride
half that of the chloroethenes
Reaction products
reacts
and carbon
were not observed.
application
with a
of hydrogen from water
and carbon tetrachloride
reaction rates on the order of 0.02 sec.‘.
with a reaction
groundwater
hydrocarbons
cell for the generation
PCE, TCE, l,l-DCE,
1,2-DCA reacts very slowly, if at all.
other observations
chlorinated
A number of
of this approach
for treating
include:
(1) Reaction rates are lowered by the presence of oxygen, but the effect on process efficiency
is not severe.
(2) The Pd catalyst is subject to a deactivation
but appears to
be related to water composition. deionized
mechanism
This de-activation
which is not yet well-understood
may be reversed by periodically
water.
(3) Electrode
materials
which include
certain platinum
group metals (ruthenium)
choices for use in this process as they tend to catalyze the recombination thus removing
the reducing agent from the reductive dehalogenation
Acknowledgments. Research
soaking the catalyst in
(LDRD) grant from Lawrence
Ken Carroll, Dwayne Coufal, Scott Kawaguchi, were instrumental and the choice
of oxygen and hydrogen into water,
reaction.
This work has been funded through a U.S. Department
and Development
materials.
Livermore
of Energy Laboratory-Directed
National Laboratory.
The efforts of
Steve Orloff, Leon Newton, Stan Rudolf, and Ken Williams
in carrying out the experiments. of electrode
may be inappropriate
Jack Harrar provided
advice on electrochemical
We also wish to thank Jack Harrar, Ken Jackson,
issues
and Martin
Reinhard for their helpful reviews of the manuscript.
References 1. M. Hudlicky, Reductions in Organic Chemistry, pp. 62-67, 181. Halstead Press, New York (1984). 2. E.J. Bouwer, B.E. Rittmann, organic compounds,
and P.L. McCarty, Anaerobic
Environmental
degradation
Science and Technology 15,596-599
of halogenated (1981).
l- and 2-carbon
936 3. M. Reinhard,
N.L. Goodman,
and J.F. Barker, Occurrence
and distribution
of organic chemicals
in two
landfill leachate plumes, El~virnnnlenral Science and Technology 18, 953-961 (1984). 4. G. Barrio-Lage,
F.Z. Parsons, R.S. Nassar, and P.A. Lorenzo, Sequential
dehalogenation
of chlorinated
ethenes, Environmentczl Science and Technology 20, 96-99 (1986). 5. T.M. Vogel,
C.S. Criddle,
Environmental
and P.L. McCarty.
Transformations
Science und Technology 21,722-136
6. P.L. McCarty, Biotic and abiotic transformations Natural Attenuation
of Chlorinated
of halogenated
aliphatic
(1987).
of chlorinated
solvents in ground water, Symposium on
in Ground Wuter, EPAl54Q/R-961509.
Orgunics
compounds,
pp 5-9, Dallas,
Texas ( 1996). 7. R.W. Gillhan, and S.F. O’Hannesin, Ground Water 32,958-967 8. T.L. Johnson.
Enhanced
degradation
of halogenated
M.M. Scherer, and P.G. Tratnyek, Kinetics of halogenated
for the treatment of contaminated
10. L.Y. Liang, N. Korte, J.D. Goodlaxson. during
organic compound
degradation
Science and Technology 30, 2634-2640 ( 1996).
9. C.G. Schreier, and M. Reinhard, Catalytic hydrodehalogenation
formation
iron,
(1994).
by iron metal, Environmental
and hydrogen
aliphatics by zero-valent
the reduction
of chlorinated
ethylenes
using palladium
water, Chemosphere 31. 3475-3487 (1995).
J. C. Clausen,
of TCE by zero-valence
Q. Fernando,
and R. Muftikian,
iron and palladized
Byproduct
iron, Ground
Water
Monitoring und Review 17, 122- 127 ( 1997).
11. U.S. Environmental pollutants:
Protection
Agency, Guidelines
for establishing
40 CFR 104.1, Part 136, U.S. Government
12. CA. Hampel,
Encyclopedia
of Electrochemistry,
test procedures
Printing Office, Washington,
pp. 869-877. Reinhold
for the analyses of D.C. (1986).
Publishing
Corporation,
New
York ( 1964). 13. CRC Handbook
of Chemistry and Physics, D.R. Lide (ed.), p. 4-21. CRC Press, Boca Raton, Florida
(1992). 14. N. Munakata, catalyzed
W. McNab, W. Haag, P.V. Roberts,
hydrodehalogenation,
American
Preprints of Papers, Vol. 37, p 168 (1997).
Chemical
and M. Reinhard, Society
Division
Effects of water matrix on Pdof‘ Environment&
Chemistry,