Abstract: A quantum dipole battery includes a positive electrode, a negative electrode, and a multilayer structure, disposed between the positive electrode and the negative electrode. The multilayer structure defines a quantum superlattice made from bilayers with each bilayer including a quantum well layer and a quantum barrier layer. The quantum well layer is separated from and coupled to adjacent quantum well layers by one of the quantum barrier layers. Excitons and indirect excitons are created and adjacent quantum wells and barriers are coupled together with quantum excitonic and ionic dipolar waves through a long range phase correlation. Electronic charges are transported by a phonon-assisted quantum tunneling or a hopping mechanism through the quantum barrier layers and the coupling of adjacent quantum well layers and quantum barrier layers results in a dipole-dipole interaction between excitonic dipoles and ionic dipoles causing Rabi splitting of energy level.

Abstract: An electric energy storage device has first and second conductor layers, a plastic sheet, a quantum dot, and positive and negative electrodes wherein the first and second conductor layers has surfaces coated with ionic or dipole material. The first conductor layer is stacked on top of the second conductor layer with a nanometer-scale interval and with the ionic material layer inbetween, forming a bilayer structure and a quantum heterostructure. Millions of bilayers are stacked together to form a multilayer structure. A positive electrode is attached to the first conductor layer and a negative electrode is attached to the last conductor layer, wherein the first and second conductor layers store electrical energy in the bilayer in a form of binding energy.

Abstract: An electric energy storage device is provided, which includes first and second conductor layers, and positive and negative electrodes. Each of the first and second conductor layers has both surfaces coated with ionic or dipole material. A bilayer is comprised of the first conductor layer and the second conductor layer and ionic material layer sandwiched between them. A multilayer structure is comprised of millions of bilayers which are stacked together one by one. The positive electrode is attached to the first conductor layer and the negative electrode is attached to the last conductor layer. The first conductor layer is stacked on top of the second conductor layer with a nanometer-scale interval and with the ionic material layer inbetween, forming a bilayer structure and a quantum heterostructure. The first and second conductor layers form a bilayer configured to store electrical energy in the bilayer in a form of binding energy.

Abstract: An electric energy storage device comprises first and second conductor layers, and positive and negative electrodes. The first conductor layer has both surfaces coated with ionic or dipole material across entire surface thereof. The second conductor layer has both surfaces coated with ionic or dipole material across entire surface thereof. The positive electrode is attached to the first conductor layer. The negative electrode is attached to the second conductor. The stored electrical energy is discharged and output to the electrodes by using an external AC voltage in a predetermined frequency range as a trigger power.

Abstract: An electric energy storage device is provided, which includes first and second conductor layers, a plastic sheet, a quantum dot, and positive and negative electrodes. Each of the first and second conductor layers has both surfaces coated with ionic or dipole material. A bilayer comprises the first conductor and second conductor layers and sandwiched ionic material layer. A multilayer structure comprises millions of bilayers which are stacked together one by one. The positive electrode is attached to the first conductor layer and the negative electrode is attached to the last conductor layer. The first conductor layer is stacked on top of the second conductor layer with a nanometer-scale interval and with the ionic material layer inbetween, forming a bilayer structure and a quantum heterostructure. The first and second conductor layers form a bilayer configured to store electrical energy in the bilayer in a form of binding energy.

Abstract: An electric energy storage device is provided, which includes first and second conductor layers, and positive and negative electrodes. Each of the first and second conductor layers has both surfaces coated with ionic or dipole material. A bilayer is comprised of the first conductor layer and the second conductor layer and ionic material layer sandwiched between them. A multilayer structure is comprised of millions of bilayers which are stacked together one by one. The positive electrode is attached to the first conductor layer and the negative electrode is attached to the last conductor layer. The first conductor layer is stacked on top of the second conductor layer with a nanometer-scale interval and with the ionic material layer inbetween, forming a bilayer structure and a quantum heterostructure. The first and second conductor layers form a bilayer configured to store electrical energy in the bilayer in a form of binding energy.

Abstract: An electric energy storage device comprises first and second conductor layers, and positive and negative electrodes. The first conductor layer has both surfaces coated with ionic or dipole material across entire surface thereof. The second conductor layer has both surfaces coated with ionic or dipole material across entire surface thereof. The positive electrode is attached to the first conductor layer. The negative electrode is attached to the second conductor. The stored electrical energy is discharged and output to the electrodes by using an external AC voltage in a predetermined frequency range as a trigger power.

Abstract: An electric energy storage device has first and second conductor layers, a plastic sheet, a quantum dot, and positive and negative electrodes wherein the first and second conductor layers has surfaces coated with ionic or dipole material. The first conductor layer is stacked on top of the second conductor layer with a nanometer-scale interval and with the ionic material layer inbetween, forming a bilayer structure and a quantum heterostructure. Millions of bilayers are stacked together to form a multilayer structure. A positive electrode is attached to the first conductor layer and a negative electrode is attached to the last conductor layer, wherein the first and second conductor layers store electrical energy in the bilayer in a form of binding energy.