Abstract: Concepts and technologies for a self-powered squeezed-light temperature regulation device are disclosed according various embodiments. The device can include an elastic anchor sheet, a thermostat regulator, a motion power transducer, and a squeezed-light cooling unit. The motion power transducer can be in electrical communication with the thermostat regulator. The squeezed-light cooling unit can be powered by the motion power transducer. The motion power transducer can include a flexible ionic diode that can be located between a first borophene sheet and a second borophene sheet, and a capacitor charge system that can be electrically connected to a collection wire that can direct an electric charge generated by the flexible ionic diode to the capacitor charge system. The squeezed-light cooling unit can include a microwave photon circuit that can create squeezed-light microwave photons and a squeezed-light cooling drum that can be in photonic communication with the microwave photon circuit.

Abstract: Concepts and technologies for a self-powered squeezed-light temperature regulation device are disclosed according various embodiments. The device can include an elastic anchor sheet, a thermostat regulator, a motion power transducer, and a squeezed-light cooling unit. The motion power transducer can be in electrical communication with the thermostat regulator. The squeezed-light cooling unit can be powered by the motion power transducer. The motion power transducer can include a flexible ionic diode that can be located between a first borophene sheet and a second borophene sheet, and a capacitor charge system that can be electrically connected to a collection wire that can direct an electric charge generated by the flexible ionic diode to the capacitor charge system. The squeezed-light cooling unit can include a microwave photon circuit that can create squeezed-light microwave photons and a squeezed-light cooling drum that can be in photonic communication with the microwave photon circuit.

Abstract: Concepts and technologies for a self-powered squeezed-light temperature regulation device are disclosed according various embodiments. The device can include an elastic anchor sheet, a thermostat regulator, a motion power transducer, and a squeezed-light cooling unit. The motion power transducer can be in electrical communication with the thermostat regulator. The squeezed-light cooling unit can be powered by the motion power transducer. The motion power transducer can include a flexible ionic diode that can be located between a first borophene sheet and a second borophene sheet, and a capacitor charge system that can be electrically connected to a collection wire that can direct an electric charge generated by the flexible ionic diode to the capacitor charge system. The squeezed-light cooling unit can include a microwave photon circuit that can create squeezed-light microwave photons and a squeezed-light cooling drum that can be in photonic communication with the microwave photon circuit.

Abstract: Concepts and technologies for a self-powered squeezed-light temperature regulation device are disclosed according various embodiments. The device can include an elastic anchor sheet, a thermostat regulator, a motion power transducer, and a squeezed-light cooling unit. The motion power transducer can be in electrical communication with the thermostat regulator. The squeezed-light cooling unit can be powered by the motion power transducer. The motion power transducer can include a flexible ionic diode that can be located between a first borophene sheet and a second borophene sheet, and a capacitor charge system that can be electrically connected to a collection wire that can direct an electric charge generated by the flexible ionic diode to the capacitor charge system. The squeezed-light cooling unit can include a microwave photon circuit that can create squeezed-light microwave photons and a squeezed-light cooling drum that can be in photonic communication with the microwave photon circuit.