Environmental Engineering Reference
In-Depth Information
REFERENCES
1.
Connor, J. R.,
Chemical Fixation and Solidification of Hazardous Wastes
, Van Nos-
trand Reinhold, New York (1990).
2.
Singh, D., A. Wagh, L. Perry, and S. Y. Jeong, Pumpable/Injectable Phosphate Bonded
Ceramics, U.S. Patent No. 6,204,214 issued March 20, 2001.
3.
Wagh, A. S. and S. Y. Jeong, Chemically Bonded Phosphate Ceramics: Part I. A
Dissolution Model of Formation. Vol. 18, No. 3, Sept. 2003, pp. 162-168, American
Ceramic Society (2003).
4.
Jeong, S. Y. and A. S. Wagh, Chemically Bonded Phosphate Ceramics — Cementing
the Gap Between Ceramics and Cements, Vol. 18, No. 3, Sept. 2003, pp. 162-168,
Mater. Technol.
(2003).
5.
Wagh, A.S., D. Singh, and S. Y. Jeong, Chemically Bonded Phosphate Ceramics,
Chapter 7-3, in
Handbook of Mixed Waste Management Technology
, C. Oh, Ed., CRC
Press, Boca Raton, FL (2001) pp. 6.3-1-6.3-18.
6.
Wagh, A. S., R. Strain, S. Y. Jeong, D. Reed, T. Krause, and D. Singh, Stabilization
of Rocky Flats Pu-Contaminated Ash within Chemically Bonded Phosphate Ceram-
ics,
J. Nucl. Mater.
265 (1999) 295-307.
7.
Singh, D., S. Jeong, A. Wagh, J. Cunnane, and J. Mayberry, Chemically Bonded
Phosphate Ceramics for Low-Level Mixed-Waste Stabilization,
J. Environ. Sci.
Health,
A32(2) (1997) 527-541.
8.
Wescott, J., R. Nelson, A. Wagh, and D. Singh, Low-Level and Mixed Radioactive
Waste In-Drum Solidification,
Practice Periodical of Hazardous, Toxic, and Radio-
active Waste Management
, Jan. (1998), pp. 4-7.
9.
Wagh, A. S., S. Y. Jeong, D. Singh, R. Strain, H. No, and J. Wescott, Stabilization
of Contaminated Soil and Wastewater with Chemically Bonded Phosphate Ceramics,
Proc. WM 97, Tucson, AZ (1997); http://www.wmsym.org/wm97proceedings/sess29/
29-0.6.htm.
10.
Singh, D., A. S. Wagh, and S.-Y. Jeong, Method for Producing Chemically Bonded
Phosphate Ceramics and for Stabilizing Contaminants Encapsulating Therein Utiliz-
ing Reducing Agents, U.S. Patent 6,133,498 (2000).
11.
Bamba, T., H. Kamizono, S. Nakayama, H. Nakamura, and S. Tashiro, Studies of
Glass Waste Form Performance at the Japan Atomic Energy Institute, in
Performance
of High Level Waste Forms and Engineered Barriers Under Repository Conditions
,
International Atomic Energy Agency Report IAEA-TECDOL-582 (1991) 165-190.
12.
Wagh, A. S., D. Singh, S. Y. Jeong, D. Graczyk, and L. B. TenKate, Demonstration
of Packaging of Fernald Silo I Waste in Chemically Bonded Phosphate Ceramic,
Proc. WM '99: Conditioning of Operational and Decommissioning Waste, Tucson,
AZ (Feb. 28-March 4, 1999); http://www.wmsym.org/wm97proceedings/
sessC9%C9%.htm.
13.
Langton, C. A., D. Singh, A. S. Wagh, M. Tlustochowicz, and K. Dwyer. Phosphate
Ceramic Solidification and Stabilization of Cesium-Containing Crystalline Silicoti-
tanate Resins,
Proc. 101st Ann. Mtg. of the American Ceramic Society
, Indianapolis
(April 25-28, 1999).
14.
Wagh, A. S., S. Y. Jeong, and D. Singh, High Strength Phosphate Cement Using
Industrial Byproduct Ashes,
Proc. First Intl. Conf. on High Strength Concrete
, Kona,
HI, A. Azizinamini, D. Darwin, and C. French, Eds., (1997) pp. 542-553.
15.
Bibler, N. E. and E. G. Orebaugh, Radiolytic Gas Production from Tritiated Waste
Forms — Gamma and Alpha Radiolysis Studies, Report No. DP-1459, Savannah
River Laboratory (1977).
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