Patent Number: 
Section: claims

1. An apparatus comprising:an internal-external hybrid nuclear reactor comprising:at least one reciprocating internal engine configured to receive internally a nanofuel comprising:a molecular mixture,wherein the molecular mixture comprises: a plurality of components mixed together, wherein at least one of said plurality of components comprises a molecule, the plurality of components of the molecular mixture comprising: i) a fissile fuel, wherein the fissile fuel comprises: a nuclide that undergoes neutron induced fission; ii) a moderator, wherein the moderator comprises: an element capable of: A) thermalizing a neutron population; and B) absorbing a fission fragment kinetic energy; and iii) a passive agent, wherein the passive agent comprises: a nuclide comprising: a resonance neutron absorption cross-section in an epithermal energy range, wherein said resonance neutron absorption cross-section of said passive agent, creates a neutron sink that increases with a nanofuel temperature; and wherein the plurality of components of the molecular mixture provide the nanofuel a nanofuel negative temperature coefficient of reactivity; andat least one external nuclear reactor integrated with said at least one reciprocating internal engine. 2. The apparatus according to claim 1, wherein said at least one reciprocating internal engine comprises at least one or more of:at least one reciprocating piston;at least one cylindrical reciprocating piston;at least one reciprocating engine comprising a plurality of pistons;at least one reciprocating rotary engine;at least one reciprocating rotary engine comprising a plurality of pistons;at least one rotary engine;at least one rotor;at least one reciprocating piston rotary engine;at least one wankel-type rotary engine; orwherein said at least one reciprocating rotary engine comprises the nanofuel placed internally to said at least one reciprocating rotary engine. 3. The apparatus according to claim 1, wherein said external nuclear reactor comprises at least one or more of:at least one plasma core assembly;at least one reflector;at least one Beryllium (Be) reflector;at least one reflector surrounded by at least one solid fuel assembly;at least one solid fuel assembly;at least one solid inverted fuel assembly;at least one core assembly;at least one channel;at least one equivalent annulus;at least one coolant;at least one cladding;at least one gap;at least one fuel;at least one cavity reactor;at least one cavity reactor that is configured to use solid fuel;at least one control drum;at least one Rover Program control drum; orat least one system for nuclear auxiliary power (SNAP) control drum. 4. The apparatus according to claim 1, wherein said internal-external hybrid nuclear reactor comprises at least one or more of:wherein said internal-external hybrid nuclear reactor comprises a compact configuration;wherein said internal-external hybrid nuclear reactor comprises being configured for military applications;wherein said internal-external hybrid nuclear reactor comprises being configured in a small transportable box;further comprising at least one cooling system;further comprising at least one reactivity control;further comprising at least one reactivity control for at least one solid fuel;further comprising at least one control drum;further comprising at least one Rover Program control drum;further comprising at least one system for nuclear auxiliary power (SNAP) control drum;further comprising at least one continuously rotating control drum; orfurther comprising at least one continuously rotating drum producing a burst of energy. 5. The apparatus according to claim 1, wherein said at least one reciprocating internal engine is configured to receive the nanofuel in at least one internal chamber. 6. The apparatus according to claim 5, wherein said at least one reciprocating internal engine is configured to receive the nanofuel in said at least one internal chamber, wherein the nanofuel is produced by a method of obtaining transuranic elements comprising:a) receiving spent nuclear fuel;b) separating transuranic elements from said spent nuclear fuel, wherein said separating comprises:separating said spent nuclear fuel into at least one stream, wherein said at least one stream comprises the transuranic elements comprising at least one or more of:any of all elements with an atomic number Z greater than 92 (Z>92);a fissile fuel;a passive agent;a fertile fuel; ora fission product. 7. The apparatus according to claim 5, wherein said at least one reciprocating internal engine is configured to operate loaded with the nanofuel, a method comprising at least one or more of:a) operating said at least one reciprocating internal engine in a spark ignition mode by injecting neutrons into the nanofuel using a source external to the nanofuel; orb) operating said at least one reciprocating internal engine in a compression ignition mode by creating neutrons in the nanofuel comprising:i) using a radioactive material that emits neutrons. 8. The apparatus configured to operate according to the method of claim 7, wherein said (a) of said operating said at least one reciprocating internal engine in said spark ignition mode by injecting neutrons into the nanofuel using said source external to the nanofuel, comprises at least one or more of:i) using a fusion neutron source; orii) using a radioactive material that emits neutrons. 9. The apparatus according to claim 1, wherein said reciprocating internal engine is configured to use the nanofuel in said reciprocating internal engine comprising:a) compressing the nanofuel in said reciprocating internal engine; andb) igniting the nanofuel using a neutron source, wherein said igniting comprises:triggering a release of nuclear energy from the nanofuel. 10. The apparatus according to claim 1, wherein said at least one reciprocating internal engine is configured to receive and use the nanofuel comprising:a) capturing release of nuclear energy from the nanofuel in said reciprocating internal engine, wherein the nanofuel is also a working fluid in said reciprocating internal engine; andb) using the energy in said working fluid to perform work. 11. The apparatus according to claim 10 wherein the using the energy in said working fluid to perform work comprises at least one or more of:driving an alternator;driving a generator;driving a propeller;generating heat;turning a shaft; orturning at least one wheel. 12. The apparatus according to claim 1, wherein said at least one reciprocating internal engine comprises:at least one engine housing; andat least one reflector. 13. The apparatus according to claim 12, wherein at least one, or more of: said at least one housing, or said at least one reflector, comprises:at least one channel. 14. The apparatus according to claim 13, wherein said at least one channel comprises at least one or more of:a coolant;a reflector; ora moderator. 15. The apparatus according to claim 1, wherein the nanofuel is received into an engine core of said at least one reciprocating internal engine, and said engine core is bounded by a first layer material. 16. The apparatus according to claim 15, wherein said first layer material has a second layer material to resist movement and to create structure. 17. The apparatus according to claim 16, wherein said first layer material comprises Beryllium and wherein said second layer material comprises cement. 18. The apparatus according to claim 1, wherein said internal-external hybrid nuclear reactor comprises at least one of:physically adjacent, or geographically adjacent to any one or more of:a nuclear reactor;a spent nuclear fuel storage facility; ora fuel fabrication facility. 19. The apparatus according to claim 1, wherein fuel of said internal-external hybrid nuclear reactor comprises fuel fabricated from spent nuclear fuel from one or more sources comprising at least one or more of:stored nuclear waste;light-water reactor spent nuclear fuel;nuclear power plant spent nuclear fuel;spent nuclear waste from at least one of: reactor, commercial, industrial, university, military, or governmental source;industrial nuclear waste; ormedical industry nuclear waste. 20. An apparatus comprising:a hybrid energy source comprising:an internal nuclear engine configured to receive internally a nanofuel comprising:a molecular mixture, wherein the molecular mixture comprises:a plurality of components mixed together, wherein at least one of said plurality of components comprises a molecule, the plurality of components of the molecular mixture comprising:i) a fissile fuel, wherein the fissile fuel comprises:a nuclide that undergoes neutron induced fission;ii) a moderator, wherein the moderator comprises:an element capable of:A) thermalizing a neutron population; andB) absorbing a fission fragment kinetic energy; andiii) a passive agent, wherein the passive agent comprises:a nuclide comprising:a resonance neutron absorption cross-section in an epithermal energy range, wherein said resonance neutron absorption cross-section of said passive agent, creates a neutron sink that increases with a nanofuel temperature; andwherein the plurality of components of the molecular mixture provide the nanofuel a nanofuel negative temperature coefficient of reactivity; andan external nuclear reactor integrated with and neutronically coupled with said internal nuclear engine. 21. The apparatus according to claim 1, wherein the at least one reciprocating internal engine provides said internal-external hybrid nuclear reactor with a compact configuration and said at least one internal reciprocating engine is neutronically coupled to said at least one external nuclear reactor. 22. The apparatus according to claim 1, comprising a housing comprising a plurality of layers comprising one or more of:an inner layer adjacent to an engine core of said at least one reciprocating internal engine;a channel;at least one outer layer comprising at least one or more of:a plurality of layers;a layer chosen from a material selected to reduce cost;a layer chosen from a material selected to improve structural integrity;a layer chosen from a material selected to provide manufacturing alternatives;a layer chosen from a material selected to add additional functionality;a sound reduction layer;a noise controlling material;an acoustic panel;a vacuum layer;a Beryllium layer;a graphite layer;an internal channel;a cooling layer;a cost reduction layer;a diagnostic layer;an instrumentation layer;a neutron reflector layer; ora material that reflects neutrons. 23. The apparatus according to claim 9, wherein the method of using the apparatus comprises:a) cooling the nanofuel with a heat exchanger; andb) returning the nanofuel to the at least one reciprocating internal engine.