Environmental Engineering Reference
In-Depth Information
55. Lin CJ, Lo SL, Liou YH: Dechlorination of trichloroethylene in aqueous solution by noble metal-
modiied iron.
J Hazard Mater
2004,
116
(3):219-228.
56. Gui L, Gillham RW, Odziemkowski MS: Reduction of N-nitrosodimethylamine with granu-
lar iron and nickel enhanced iron. 1. Pathways and kinetics.
Environ Sci Technol
2000,
34
(16):
3489-3494.
57. Lee CC, Doong RA: Dechlorination of tetrachloroethylene in aqueous solutions using metal-
modiied zerovalent silicon.
Environ Sci Technol
2008,
42
(13):4752-4757.
58. Schlicker O, Ebert M, Fruth M, Weidner M, Wust W, Dahmke A: Degradation of TCE with iron:
The role of competing chromate and nitrate reduction.
Ground Water
2000,
38
(3):403-409.
59. Dries J, Bastiaens L, Springael D, Agathos SN, Diels L: Combined removal of chlorinated
ethenes and heavy metals by zerovalent iron in batch and continuous low column systems.
Environ Sci Technol
2005,
39
(21):8460-8465.
60. Lien HL, Jhuo YS, Chen LH: Effect of heavy metals on dechlorination of carbon tetrachloride by
iron nanoparticles.
Environ Eng Sci
2007,
24
(1):21-30.
61. Xie L, Shang C: Chemical reduction of bromate in the presence of humic acid and ferric ions.
Abstr Pap Am Chem S
2004,
228
:U607-U608.
62. Jeong HY, Hayes KF: Impact of transition metals on reductive dechlorination rate of hexachlo-
roethane by mackinawite.
Environ Sci Technol
2003,
37
(20):4650-4655.
63. O'Loughlin EJ, Burris DR: Reduction of halogenated ethanes by green rust.
Environ Toxicol
Chem
2004,
23
(1):41-48.
64. O'Loughlin EJ, Kemner KM, Burris DR: Effects of Ag-I, Au-III, and Cu-II on the reductive
dechlorination of carbon tetrachloride by green rust.
Environ Sci Technol
2003,
37
(13):2905-2912.
65. Maithreepala RA, Doong RA: Synergistic effect of copper ion on the reductive dechlorination of
carbon tetrachloride by surface-bound Fe(II) associated with goethite.
Environ Sci Technol
2004,
38
(1):260-268.
66. Maithreepala RA, Doong RA: Enhanced dechlorination of chlorinated methanes and ethenes
by chloride green rust in the presence of copper(II).
Environ Sci Technol
2005,
39
(11):4082-4090.
67. Arnold WA, Roberts AL: Kinetics of chlorinated ethylene reaction with zero-valent iron in col-
umn reactors.
Abstr Pap Am Chem S
2000,
219
:U620-U620.
68. Li T, Farrell J: Electrochemical investigation of the rate-limiting mechanisms for trichloroethylene
and carbon tetrachloride reduction at iron surfaces.
Environ Sci Technol
2001,
35
(17):3560-3565.
69. Weber EJ: Iron-mediated reductive transformations: Investigation of reaction mechanism.
Environ Sci Technol
1996,
30
(2):716-719.
70. Stumm W, Sulzberger B: The cycling of iron in natural environments—Considerations
based on laboratory studies of heterogeneous redox processes.
Geochim Cosmochim Ac
1992,
56
(8):3233-3257.
71. Clark CJ, Rao PSC, Annable MD: Degradation of perchloroethylene in cosolvent solutions by
zero-valent iron.
J Hazard Mater
2003,
96
(1):65-78.
72. Johnson TL, Fish W, Gorby YA, Tratnyek PG: Degradation of carbon tetrachloride by iron metal:
Complexation effects on the oxide surface.
J Contam Hydrol
1998,
29
(4):379-398.
73. Loraine GA: Effects of alcohols, anionic and nonionic surfactants on the reduction of PCE and
TCE by zero-valent iron.
Water Res
2001,
35
(6):1453-1460.
74. Alessi DS, Li ZH: Synergistic effect of cationic surfactants on perchloroethylene degradation by
zero-valent iron.
Environ Sci Technol
2001,
35
(18):3713-3717.
75. Tratnyek PG, Scherer MM, Deng BL, Hu SD: Effects of natural organic matter, anthropogenic
surfactants, and model quinones on the reduction of contaminants by zero-valent iron.
Water
Res
2001,
35
(18):4435-4443.
76. Cho HH, Park JW: Reactive dechlorination of PCE using zero valent iron plus surfactants.
ACS
Sym Ser
2003,
837
:141-153.
77. Muftikian R, Nebesny K, Fernando Q, Korte N: X-ray photoelectron spectra of the palladium-
iron bimetallic surface used for the rapid dechlorination of chlorinated organic environmental
contaminants.
Environ Sci Technol
1996,
30
(12):3593-3596.
