Concentration and removal of tritium and/or deuterium from...

Electrolysis: processes – compositions used therein – and methods – Electrolytic material treatment – Water – sewage – or other waste water

Reexamination Certificate

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C205S688000, C205S759000, C205S760000, C588S253000

Reexamination Certificate

active

06190531

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates, in general, to concentration of a hydrogen isotope (i.e., tritium and/or deuterium) that is a contaminant in H
2
O, followed by separation of the concentrate from the H
2
O. More particularly, the present invention relates to first converting the tritium or deuterium into an organic substrate (and also, some of the H
2
O will be converted into the protio form of the organic substrate), followed by electrolysis in the presence of certain metal oxo complexes. This will oxidize the protio form of the organic substrate and produce hydrogen gas and the oxidized form of the organic substrate. Oxidation by the electrolysis of the tritio form of the organic substrate or of the deuterio form of the organic substrate will be negligible, due to differences in the respective rate constants for the respective reactions of the tritio form and deuterio form as compared to the protio form. Consequently, the tritio form of the organic substrate and/or the deuterio form of the organic substrate will be concentrated in the H
2
O, and can subsequently be removed from the H
2
O.
Table of Abbreviations
PhCH
2
OH
benzyl alcohol
cm
centimeter
D
deuterium (also often
designated as
2
H)
D
2
O
deuterium heavy water (also
known as deuterium oxide)
HDO
deuteriated light water
DPM
disintegrations per minute
EtOH
ethyl alcohol
g
gram
H
hydrogen
H
2
hydrogen gas
H
2
O
2
hydrogen peroxide
ITO
indium tin oxide (also known
as tin-doped indium oxide
namely, In
2
O
3
:Sn)
IR
infrared
H
2
O
light water
&mgr;A
microampere
ml
milliliter
mmole
millimole
M
molar
NHS
N-hydroxy succinimide
EDC
1-(3-dimethylaminopro-
pyl)-3-ethylcarbodiimide
hydrochloride
Ph
phenyl
H
+
proton
k
obs
pseudo first-order rate
constant measured in
seconds
−1
py
pyridine
[Ru
IV
(bpy)
2
(py)(O)]
2+
C
25
H
16
N
5
ORu
2+
[Ru
II
(bpy)
2
(py)(H
2
O)]
2+
C
25
H
18
N
5
ORu
2+
[Ru
IV
(tpy)(bpy)(O)]
2+
C
25
H
14
N
5
ORu
2+
[Ru
III
(tpy)(bpy)(OH)]
2+
C
25
H
15
N
5
ORu
2+
SSCE
saturated sodium chloride
electrode
HTO
tritiated light water
DTO
tritiated heavy water
T
tritium (also often designated
as
3
H)
T
2
O
tritium oxide
bpy
2,2′-bipyridine
tpy
2,2′:6′,2″-terpyridine
V
volt
BACKGROUND OF THE INVENTION
As discussed by Cotton and Wilkinson, pp. 216-217,
Advanced Inorganic Chemistry
(1967), T is formed continuously in the upper atmosphere of the earth by cosmic ray-induced nuclear reactions. Accordingly, fast neutrons derived from cosmic ray reactions can produce T by the reaction
14
N(
n,
3
H)
12
C
and T is radioactive with a half-life of about 12.4 years. Also, T is made artificially in nuclear reactors, for instance, by the bombardment of lithium with thermal neutrons to form tritium with the emission of alpha particles, according to the formula
6
Li(
n,
&agr;)
3
H
and is commercially available.
As also discussed by Cotton and Wilkinson, D as D
2
O is separated from H
2
O by fractional distillation or electrolysis and by utilization of very small differences in the free energies of the H and D forms of different compounds. D
2
O is commercially available and used as a moderator in nuclear reactors, and also used widely in the study of reaction mechanisms and of spectroscopic mechanisms.
More specifically, as is mentioned in many of the patents cited below, T can be found in nuclear fuel reprocessing plants, waste streams from military operations connected with nuclear weapons programs, and nuclear power reactors that employ D
2
O as a moderator and/or coolant. Presently, T is removed from H
2
O and D
2
O by various gaseous hydrogen separation techniques, such as distillation of H
2
O, cryogenic distillation of gaseous hydrogen, and the like. Additionally, T
2
O can be concentrated from DTO contaminated D
2
O by various processes such as vacuum distillation or electrolytic cascade (several stages of water electrolysis), but such processes are of limited use because of the high toxicity of T
2
O, the low separation factor for distillation, and the high power consumption for the electrolizers. Thus, it is more practical either to convert DTO into the elemental T such as by electrolysis, or to extract T from the water by catalytic exchange with a deuterium stream. Then, the much less toxic elemental T can be enriched by known processes such as cryogenic distillation.
Of interest, each of Canadian Patent No. 1,137,025 issued Dec. 7, 1982 to Dombra, U.S. Pat. No. 4,190,515 issued Feb. 26, 1980 to Butler and Hammerli, and U.S. Pat. No. 4,228,034 issued Oct. 14, 1980 to Butler, Rolston, den Hartog, Molson, and Goodale (all three patents assigned to Atomic Energy of Canada Limited) disclose processes and/or apparatuses for the removal of D and/or T from water.
Also of interest, Japanese Patent No. 61028426 published Feb. 8, 1986 to Masakazu (assigned to Japan Atom Energy Research Institute) discloses a process to concentrate and to recover T as T
2
or D as D
2
from a gaseous mixture consisting of H
2
, HT, and T
2
or of H
2
, HD, or D
2
, respectively, by a system including an isotope separation column and a catalytic reaction column. Additionally, Japanese Patent No. 8026703 published Jan. 30, 1996 to Masaaki (assigned to Permelec Electrode Limited) discloses a process to obtain D by electrolyzing an electrolyte, as water containing D in an electrolytic cell divided into an anode compartment and a cathode compartment, with an ion exchange membrane. According to Masaaki, the process does not cause problems due to explosions from hydrogen and oxygen since they are mixed and recombined into water.
Of background interest with respect to Ru complexes employed in the present invention, McHatton and Anson, “Electrochemical Behavior of Ru(trpy)(bpy)(OH
2
)
3+
in Aqueous Solution and When Incorporated in Nafion Coatings”, Vol. 23,
Inorganic Chemistry,
pp. 3935-3942 (1984) describe that polypyridyl complexes of Ru that contain at least one water ligand, when in a Nafion (NAFION 117® is a fluorinated polymer sold by DuPont and having the formula
where x and y are the number of repeating monomer units) coating on a graphite electrode can be oxidized to the corresponding oxo complexes of Ru
IV
. Also background, Moss, Argazzi, Bignozzi, and Meyer, “Electropolymerization of Molecular Assemblies”, Vol. 36,
Inorganic Chemistry,
pp. 762-763 (1997) describe that electropolymerization of appropriately derivatized metal complexes on conducting substrates leads to electroactive thin films, and one approach was reduction of vinyl-containing polypyridyl complexes such as Ru(vbpy)
3
2+
, where vbpy is 4-methyl-4′-vinyl-2,2′-bipyrindine.
Additionally, Roecker (a coworker at the University of North Carolina of one of the inventors (Meyer) of the subject invention) and Meyer had investigated the kinetics and mechanism of the oxidation of a number of alcohol organic substrates by a bipyridine-pyridine ruthenium
IV
oxo complex, namely [Ru
IV
(bpy)
2
(py)(O)](ClO
4
)
2
in order to provide [Ru
IV
(bpy)
2
(py)(O)]
2+
, for comparing the protio form of the alcohol organic substrate to the deuterio form of the organic substrate. Their work revealed large, primary deuterium kinetic isotope effects for benzyl alcohol, namely for PhCH
2
OH compared to PhCD
2
OH. See, Roecker and Meyer, “Hydride Transfer in the Oxidation of Alcohols by [(bpy)
2
(py)Ru(O)]
2+
. A k
H
/k
D
Kinetic Isotope Effect of 50”, Vol. 109,
Journal of the American Chemical Society,
No. 3, pp. 746-754 (1987).
For instance, Roecker and Meyer found that oxidation of benzyl alcohol (as the organic substrate) by the bipyridine-pyridine ruthenium
IV
oxo complex, as shown by the equation
[Ru
IV
(bpy)
2
(py)(O)]
2+
+PhCH
2
OH→[Ru
II
(bpy)
2
(py)(OH
2
)]
2+
+PhCHO
displayed a deuterium kinetic isotope effect that exhibited a ratio of rate constants of
k
(C—H)/
k
(C—D)=50
while displaying no significant H
2
O/D
2
O solvent isotope effect

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