Recently, catalytic oxidation in supercritical water (SCW) has
received considerable research
attention. The major thrust of this current research effort is
attributable to the rapid
development of supercritical water oxidation (SCWO) as an innovative
wastewater treatment
technology. The incentives of catalyst-enhanced processes may
include increased reaction rates,
reduced residence times and temperatures, and optimized reaction
pathways that are otherwise
difficult to achieve through noncatalytic processes. However, the
databases associated with
the use of catalysts in SCWO are limited. The purpose of this
paper is to (1) review catalytic
enhancement and technology as related to SCWO; (2) analyze effects of
SCW on catalysts and
catalytic SCWO processes; and (3) present a catalyst development
strategy for SCWO-related
applications. Catalyst activity and stability (in terms of
reaction kinetics, surface phenomena,
and phase behavior of catalysts in SCW) are emphasized. The paper
presents a useful database,
provides guidelines for catalyst selection, and illustrates how
effective use of catalyst may enhance
SCWO process development.
Catalytic oxidation of ammonia in supercritical water
(SCW) was studied using a continuous-flow, packed-bed reactor at temperatures ranging from 410 to 470 °C, a
nominal pressure of
27.6 MPa, and reactor residence times of less than 1 s. The
kinetics and catalyst performance
of MnO2/CeO2 for oxidation of ammonia in SCW
was evaluated. In this reaction environment,
ammonia was predominantly converted into molecular nitrogen
(N2), and the rate of ammonia
conversion was enhanced by MnO2/CeO2. For
example, 40% of the ammonia was converted
when using the MnO2/CeO2 catalyst at a
temperature of 450 °C and a reactor residence time of
0.8 s. It was reported that, without a catalyst, essentially no
ammonia conversion was observed
below 525 °C (Helling, R. K.; Tester, J. W. Environ. Sci.
Technol.
1988, 22 (11), 1319) and
10%
of the ammonia was converted at a temperature of 680 °C, a pressure
of 24.6 MPa, and a reactor
residence time of 10 s (Webley, P. A.; Tester, J. W.; Holgate, H. R.
Ind.
Eng.
Chem.
Res.
1991,
30 (8), 1745). Kinetic models developed for the
gas-phase catalytic oxidation of ammonia were
adopted and proven to be adequate for catalytic oxidation of ammonia in
supercritical water.
The best-fit global rate expression for catalytic supercritical
water oxidation of ammonia by
MnO2/CeO2 was obtained as follows:
r = 1.14 × 1014 exp(−189
kJ/mol/RT)
[NH3]0.63[O2]0.71.
The
BET surface area and X-ray diffraction analyses of the exposed catalyst
indicated a significant
reduction of surface area and changes in the crystalline structure of
the catalyst.
An electrochemical thiocyclization of N-allylthioamides has been developed for the synthesis of SCN-containing 2-thiazolines and NCS-containing thiazines.
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