A thermomagnetic apparatus for electric power production, comprising: a hollow toric vessel (30) delimited by a wall (31) having an outer toric surface (31a) having a toroidal direction, wherein the toric wall (31) encloses a volume containing a ferrofluid which comprises magnetic nanoparticles dispersed or suspended in a fluid carrier; a plurality of hydraulic conduits (36-39) in thermal contact with the outer toric surface (31a); a magnetic field source (62) coupled to the outer toric surface (62) and an extraction coil (65) which comprises a plurality of turns (65′) of electrical conductor wire arranged on the outer toric surface (31a).

A thermomagnetic apparatus for electric power production, comprising: a hollow toric vessel (30) delimited by a wall (31) having an outer toric surface (31a) having a toroidal direction, wherein the toric wall (31) encloses a volume containing a ferrofluid which comprises magnetic nanoparticles dispersed or suspended in a fluid carrier; a plurality of hydraulic conduits (36-39) in thermal contact with the outer toric surface (31a); a magnetic field source (62) coupled to the outer toric surface (62) and an extraction coil (65) which comprises a plurality of turns (65′) of electrical conductor wire arranged on the outer toric surface (31a).

A magnetohydrodynamic cavitation fusion energy generator comprising an internal armature rotatably arranged within a reactor vessel. The generator further comprises a lithium-ammonia fuel dispersed between the internal armature and the reactor vessel. The reactor vessel further comprises a plurality of external magnets and at least one extraction electrode configured to extract current from fusion reactions in the fuel. The internal armature further comprises a plurality of cavitation cavities, a plurality of internal magnets, and at least one facilitation electrode configured to arc for the facilitation of fusion. The plurality of internal magnets and the plurality of external magnets are arranged relative to one another to create a magnetic field within the reactor vessel when the internal armature is rotated relative to the reactor vessel.

A magnetohydrodynamic cavitation fusion energy generator comprising an internal armature rotatably arranged within a reactor vessel. The generator further comprises a lithium-ammonia fuel dispersed between the internal armature and the reactor vessel. The reactor vessel further comprises a plurality of external magnets and at least one extraction electrode configured to extract current from fusion reactions in the fuel. The internal armature further comprises a plurality of cavitation cavities, a plurality of internal magnets, and at least one facilitation electrode configured to arc for the facilitation of fusion. The plurality of internal magnets and the plurality of external magnets are arranged relative to one another to create a magnetic field within the reactor vessel when the internal armature is rotated relative to the reactor vessel.

Embodiments of an apparatus for generating electric power from flowing seawater are disclosed. Embodiments form fluid channels having magnetic fields through which seawater will flow. Electrodes are arranged with respect to the fluid channels and connected together such that electric power is generated as seawater flows through the channels.

Embodiments of an apparatus for generating electric power from flowing seawater are disclosed. Embodiments form fluid channels having magnetic fields through which seawater will flow. Electrodes are arranged with respect to the fluid channels and connected together such that electric power is generated as seawater flows through the channels.

A thermomagnetic apparatus for electric power production, comprising: a hollow toric vessel (30) delimited by a wall (31) having an outer toric surface (31a) having a toroidal direction, wherein the toric wall (31) encloses a volume containing a ferrofluid which comprises magnetic nanoparticles dispersed or suspended in a fluid carrier; a plurality of hydraulic conduits (36-39) in thermal contact with the outer toric surface (31a); a magnetic field source (62) coupled to the outer toric surface (62) and an extraction coil (65) which comprises a plurality of turns (65′) of electrical conductor wire arranged on the outer toric surface (31a).

A thermomagnetic apparatus for electric power production, comprising: a hollow toric vessel (30) delimited by a wall (31) having an outer toric surface (31a) having a toroidal direction, wherein the toric wall (31) encloses a volume containing a ferrofluid which comprises magnetic nanoparticles dispersed or suspended in a fluid carrier; a plurality of hydraulic conduits (36-39) in thermal contact with the outer toric surface (31a); a magnetic field source (62) coupled to the outer toric surface (62) and an extraction coil (65) which comprises a plurality of turns (65′) of electrical conductor wire arranged on the outer toric surface (31a).

Embodiments of an apparatus for generating electric power from flowing seawater are disclosed. Embodiments form fluid channels having magnetic fields through which seawater will flow. Electrodes are arranged with respect to the fluid channels and connected together such that electric power is generated as seawater flows through the channels.

Embodiments of an apparatus for generating electric power from flowing seawater are disclosed. Embodiments form fluid channels having magnetic fields through which seawater will flow. Electrodes are arranged with respect to the fluid channels and connected together such that electric power is generated as seawater flows through the channels.