Nuclear fusion fuel

Abstract

A fuel for nuclear fusion where the fusion fuel is compressible for producing fusion with lasers (22) or other means. The fusion fuel comprises a catalytic material mixed with a deuteride of an alkaline earth metal or alkali metal. The catalytic material may comprise a mixture or a compound containing red phosphorus, and a transition metal from Period 4 or Period 5 of the Periodic table. The fusion fuel is cheap and easy to manufacture, and the technology for compression is already available. There is a realistic prospect of commercially producing nuclear fusion energy.

Claims

1-13. (canceled)

14. A fusion fuel compositionally comprising a catalytic material mixed with a deuteride of an alkaline earth metal or alkali metal, wherein said catalytic material comprises a mixture or compound containing red phosphorous (P) and a transition metal from Period 4 or Period 5 of the Periodic table.

15. The fusion fuel of claim 14, wherein said deuteride is of an alkaline earth metal.

16. The fusion fuel of claim 15, wherein said deuteride is of calcium (Ca).

17. The fusion fuel of claim 14, wherein said transition metal is from Period 4 of the Periodic table.

18. The fusion fuel of claim 17, wherein said transition metal is manganese (Mn).

19. The fusion fuel of claim 14, wherein the fuel comprises a mixture of powders of the deuteride and catalytic material.

20. The fusion fuel of claim 14, wherein said fuel is configured to be compressed using a number of incident beams of laser radiation, or electrons, or ions, or atoms, or high velocity particles.

21. The fusion fuel of claim 14, wherein said fuel is configured to be compressed using a mechanical force, or a shockwave, or a grinding action, or a mill.

22. The fusion fuel of claim 14, wherein said fuel is configured to be compressed by propelling a pellet or a capsule of said fuel against an object.

23. The fusion fuel of claim 14, wherein said fuel is configured to be compressed by using a Z-pinch effect.

24. The fusion fuel of claim 14, wherein the fuel is further configured to be heated using an external heat source, or a hot filament, or an electric spark discharge, or an incident beam of laser radiation, or electrons, or ions, or atoms, or high velocity particles.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] The drawings illustrate six embodiments of apparatus for carrying out the method of the invention, all of which have been tested successfully by the Applicant. These are shown in FIGS. 1 to 6, which will be described in more detail below. Also described below are various feasible embodiments of apparatus for commercial fusion energy generation using the method of the invention, which are shown in FIGS. 7 to 10.

DETAILED DESCRIPTION

[0019] For demonstrating the reality of solid state nuclear fusion, the following procedures were performed many times, resulting in strong reactions which could not be attributed to normal chemical exothermic processes.

[0020] In one embodiment, a fusion fuel compositionally comprises a catalytic material mixed with a deuteride of an alkaline earth metal or alkali metal, wherein said catalytic material comprises a mixture or compound containing red phosphorous (P) and a transition metal from Period 4 or Period 5 of the Periodic table. This fusion fuel is compressible for producing nuclear fusion. Compression of this fuel for nuclear fusion is described herein.

[0021] The most successful experiments employed fusionable material, calcium deuteride, which was produced by heating pieces of calcium in an atmosphere of deuterium in a silica flask. This was ground with mortar and pestle, and then mixed with similar weights of a catalytic material comprising red phosphorus powder and manganese powder, to yield the basic prescribed fusion-fuel.

[0022] It is anticipated that other alkaline earth or alkali metals would work in place of calcium, because their primary function would be to fix the deuterium. Indeed, further experiments using the deuterides of magnesium, strontium, barium, lithium and sodium have provided satisfactory results. Similarly, transition elements in Periods 4 and 5 have wide-ranging catalytic properties and are likely to work in place of manganese to an acceptable degree (see www.sigmaaldrich.com/chemistry/chemistry-products.html?TablePage=16257685). Satisfactory results have been achieved using fusion fuels comprising mixtures of powders of calcium deuteride, red phosphorus and each one of the following: scandium, titanium, vanadium, chromium, manganese, iron, cobalt, nickel, copper, zinc, yttrium, zirconium, niobium, molybdenum and cadmium. The person skilled in the art will be able to select a suitable transition metal for use in any particular set of circumstances, in order to optimise the method for either energy generation or helium production.

[0023] FIG. 1 shows one successful embodiment of the fusion fuel which was compressed and produced fusion, where compression was carried out by a process consisting of a case-hardened steel bearing rod 2 with shoulder 3, to be pushed through a shaped steel sleeve 4 containing the said fusion fuel 1. (Figure scale is approximately 1:1). The fusion fuel was put around a case-hardened steel bearing rod with a shoulder to compress the fusion-fuel as it was pushed through a shaped sleeve. A press-fit between rod and sleeve was specified to contain the fusion-fuel and gases. Upon applying several tons of force, shear occurred in the compacted fusion-fuel under the shoulder and ignited fusion which broke many pieces off the rod shoulder and even melted the nearby surface in places. This allowed the generated gas pressure and fusion process to subside without progressing to a runaway situation. FIG. 2 shows line drawings and photographs of two typical rods 2 with broken shoulders 3, which indicate that extreme pressure pulses must have been generated to do such damage on bearing steel. The originally shiny steel surface was scorched and eroded all around. After extracting the rod from the steel sleeve, inspection of the sleeve interior revealed a melted burnt appearance.

[0024] FIG. 3 shows another successful embodiment of the fusion process in which the said fusion fuel 1 was put in a compression cell consisting of two hardened steel roller bearings 5, 6, in a steel sleeve 7 with a solder seal 8 to contain the fusion-fuel and gases. (FIG. 3 scale is approximately 1:1). It was subjected to a pressure of 25 tons per square centimetre in a press, to form a solid pellet of fusion-fuel. The force was then removed and a steel wedge placed under the cell. As pressure was resumed, some shear occurred within the fusion-fuel pellet, and ignition of fusion occurred at a localised hot-spot in the shear-plane within the pressurised environment. FIG. 4 illustrates line drawing representations and photographs of two separate examples, wherein the fusion gas pressure was great enough over a surface area of 1 mm4 mm to create a cutting wedge of steel 6C within the lower bearing surface, which then cleaved that bearing into pieces 6A, 6B. The wedge shown 6C was retrieved in one case. In many cases, the bearings were shattered and fusion ceased as the gases were able to escape and reduce pressure.

[0025] FIG. 5 shows an embodiment for producing persistent fusion wherein the said fusion fuel 1 was heated in a cell by a diesel-engine glow-plug 9, while being compressed by a screw 10 and monitored by an accelerometer 11 and thermocouple 12.

[0026] FIG. 6 shows an embodiment for producing fusion using a direct hot wire effect, wherein the fusion fuel 1 was compressed by screw 10 and heated by a wire 13 carried by ceramic-metal seals 14.

[0027] FIG. 7 shows an embodiment to produce fusion for commercial energy generation wherein the said fusion-fuel pellet 1 is suspended from a support 21 and compressed by one or more laser beams 22 or particle beams 22, contained overall within a heat exchanger 20 to produce steam for electricity generation

[0028] FIG. 8 shows an embodiment to produce fusion for commercial energy generation, wherein the said fusion fuel 1 is contained within a Z-pinch cell 23, suspended from a support 21, and compressed by firing the cell via conductors 24 within an overall heat exchanger 20 to produce steam for electricity generation.

[0029] FIG. 9 shows an embodiment to produce fusion for commercial energy generation, wherein the said fusion-fuel 1 is encapsulated and propelled by a system 24, so as to collide with another capsule 25 from system 26 or a stationary capsule, in order to cause fusion within an overall heat exchanger 20 to produce steam for electricity generation.

[0030] FIG. 10 shows an embodiment of a rolling compression/grinding process to produce fusion energy, wherein the fusion-fuel 1 is compressed between a rotating driven roller 15 and a slave roller 16 to cause fusion such that the resulting hot gases 19 produce force on adjacent turbine blades, to enhance roller rotation and are contained by an overall closed heat exchanger 20 which maintains an inert environment and produces steam for electricity generation.

[0031] The fusion fuel described herein and the process for compressing said fuel to produce nuclear fusion is a type of Low Energy Nuclear Reaction (LENR), a field that includes nuclear transmutations by electron capture and radioactive decay.

[0032] The fusion fuel described herein can be used as a new type of fuel for Inertial Confinement Fusion (ICF) which is currently being developed at the National Ignition Facility. Standard ICF required very high pressure and temperature when using elemental deuterium and tritium as fuel. In contrast, the fusion fuel and process of compressing with optional heating of the fusion fuel as described herein is a solid state fusion processing using a deuterium component and a catalyst at around 25 tons/cm2 and 1000C within shear hot-spots. Without being bound by theory, it is believed that the catalyst described herein makes it possible to achieve solid state fusion at much lower temperature than the standard pure deuterium and tritium.

[0033] Having disclosed the general principle by which nuclear fusion may be achieved, the person skilled in the art will understand how to put that principle into practice in order to generate power and/or to produce helium. The embodiments described above are merely examples and are not intended to restrict the scope of the invention in any way. The scope of the invention is, on the contrary, defined by the following claims.