[1] National Academy of Sciences (1957). The Disposal of Radioactive Waste on Land.

[2] O’Brien, M.T, L.H. Cohen, T.N. Narasimhan, T.L. Simkin, H.A. Wollenberg, W.F. Brace, S. Green, H.P. Platt, (1979), The Very Deep Hole Concept: Evaluation of an Alternative for Nuclear Waste Disposal, Berkeley, CA, Lawrence Berkeley Laboratory, LBL-7089.

[3] Woodward-Clyde Consultants (1983). Very Deep Hole Systems Engineering Studies. Columbus, OH, ONWI.

[4] Juhlin, C. and H. Sandstedt (1989). Storage of Nuclear Waste in Very Deep Boreholes: Feasibility Study and Assessment of Economic Potential. Part I: Geological Considerations. Part II: Overall Facility Plan and Cost Analysis., Svensk Karnbranslehantering AB.

[5] Heiken, G., G. Woldegabriel, R. Morley, H. Plannerer, and J. Rowley (1996). Disposition of excess weapon plutonium in deep boreholes – site selection handbook. Los Alamos, NM, Los Alamos National Laboratory.

[6] Nirex (2004). A Review of the Deep Borehole Disposal Concept, Report N/108, United Kingdom Nirex Limited.

[7] Gibb, F. G. F., N. A. McTaggart, et al. (2008). “High-density support matrices: Key to the deep borehole disposal of spent nuclear fuel.” J. of Nuclear Materials 374: 370-377.

[8] Brady, P. V., B. W. Arnold, G. A. Freeze, P. N. Swift, S. J. Bauer, J. L. Kanney, R. P. Rechard, and J. S. Stein (2009). Deep Borehole Disposal of High-Level Radioactive Waste, SAND2009-4401, Albuquerque, NM, Sandia National Laboratories.

[9] Hoag, C. I. (2006). Canister design for deep borehole disposal of nuclear waste. Dept of Nuclear Engineering. Cambridge, MA, MIT.

[10] Anderson, V. K. (2004). An Evaluation of the Feasibility of Disposal of Nuclear Waste in Very Deep Boreholes. Dept. of Nuclear Engineering. Cambridge, MA, MIT.

[11] IAEA (International Atomic Energy Agency) (2006), “Geological Disposal of Radioactive Waste: Safety Requirements,” IAEA Safety Standards Series No.WS-R-4, Jointly sponsored by the International Atomic Energy Agency and the Organisation for Economic Cooperation and Development Nuclear Energy Agency, Vienna.

[11] F.G.F. Gibb, K.P. Travis, N.A.McTaggart, D. Burley & K.W. Hesketh. 2008. Modelling temperature distribution around very deep borehole disposals of HLW. Nuclear Technology, 163, 62-73.

[13] F.G.F. Gibb, K.P. Travis, N.A.McTaggart & D. Burley. 2008. A model for heat flow in deep borehole disposals of high-level nuclear waste. Journal of Geophysical Research, 113, BO5201. doi:10.1029/2007JB005081.

[14] L. Birgersson, K. Skagius, M. Wiborgh & H. Widen. 1992. SKB Technical Report 92-43.

[15] F.G.F. Gibb. 1999. High-temperature, very deep, geological disposal: A safer alternative for high-level radioactive waste. Waste Management, 19, 207-211.

[16] F.G.F. Gibb, K.J. Taylor & B.E. Burakov. 2008. The ‘granite encapsulation’ route to the safe disposal of Pu and other actinides. Journal of Nuclear Materials, 374, 364-369.

[17] J. Beswick. 2008. . Status of technology for deep borehole disposal. Report for NDA by EPS International, Contract No. NP 01185.


Related Articles
Into the deep
Deep borehole disposal (DBD) methods
Looking down the bore