Abstract: A metadielectric composite oligomeric organic material according to the formula: wherein C is a linear chain oligomeric polarizable core with a system of conjugated multiple and single bonds wherein the linear chain oligomeric polarizable core possesses at least two different monomers with differing electron affinity, and the different monomers are positioned within the linear chain oligomeric polarizable core such that an electron affinity gradient is present, and the differing monomers have a low HOMO-LUMO bandgap between them, and there is at least one electron-donor group, D, attached to the linear chain oligomeric polarizable core, there is at least one electron-acceptor group, A, is attached to the linear chain oligomeric polarizable core, p? and q? represent the number of electron-donor and electron-acceptor groups present, respectively, and are any integer greater than zero, and at least one resistive insulating group is covalently attached to the molecular structure at any location.

Abstract: An electro-polarizable compound has the following general formula: Core1 is an aromatic polycyclic conjugated molecule having two-dimensional flat form and that self-assembles to form supramolecular structures. R1 are electron donor groups connected to Core1 and R1? are electron acceptor groups connected to Corel, m is number of acceptor groups R1, m? is a number of donor groups R?. The numbers m and m? are equal to 0, 1, 2, 3, 4, 5 or 6, but both m and m? are not both equal to 0. R2 is a substituent comprising one or more ionic groups connected to Core1 directly or via a connecting group; a number p of ionic groups R2 is 0, 1, 2, 3 or 4. The fragment marked NLE has a nonlinear effect of polarization. Core2 is a self-assembling electro-conductive oligomer, a number n of the such oligomers is 0, 2, or 4. R3 is a substituent comprising one or more ionic groups connected to Core2; a number s of the ionic groups R3 is 0, 1, 2, 3 or 4.

Abstract: A metadielectric composite oligomeric organic material according to the formula: wherein C is a linear chain oligomeric polarizable core with a system of conjugated multiple and single bonds wherein the linear chain oligomeric polarizable core possesses at least two different monomers with differing electron affinity, and the different monomers are positioned within the linear chain oligomeric polarizable core such that an electron affinity gradient is present, and the differing monomers have a low HOMO-LUMO bandgap between them, and there is at least one electron-donor group, D, attached to the linear chain oligomeric polarizable core, there is at least one electron-acceptor group, A, is attached to the linear chain oligomeric polarizable core, p? and q? represent the number of electron-donor and electron-acceptor groups present, respectively, and are any integer greater than zero, and at least one resistive insulating group is covalently attached to the molecular structure at any location.

Abstract: A metadielectric composite oligomeric organic material according to Formula shown in FIG. 4 wherein C is a linear chain oligomeric polarizable core with a system of conjugated multiple and single bonds wherein the linear chain oligomeric polarizable core possesses at least two different monomers with differing electron affinity, and the different monomers are positioned within the linear chain oligomeric polarizable core such that an electron affinity gradient is present, and the differing monomers have a low HOMO-LUMO bandgap between them, and there is at least one electron-donor group, D, attached to the linear chain oligomeric polarizable core, there is at least one electron-acceptor group, A, is attached to the linear chain oligomeric polarizable core, p? and q? represent the number of electron-donor and electron-acceptor groups present, respectively, and are any integer greater than zero, and at least one resistive insulating group is covalently attached to the molecular structure at any location.

Abstract: A metadielectric composite oligomeric organic material according to the formula: wherein C is a linear chain oligomeric polarizable core with a system of conjugated multiple and single bonds wherein the linear chain oligomeric polarizable core possesses at least two different monomers with differing electron affinity, and the different monomers are positioned within the linear chain oligomeric polarizable core such that an electron affinity gradient is present, and the differing monomers have a low HOMO-LUMO bandgap between them, and there is at least one electron-donor group, D, attached to the linear chain oligomeric polarizable core, there is at least one electron-acceptor group, A, is attached to the linear chain oligomeric polarizable core, p? and q? represent the number of electron-donor and electron-acceptor groups present, respectively, and are any integer greater than zero, and at least one resistive insulating group is covalently attached to the molecular structure at any location.

Abstract: An electro-polarizable compound has the following general formula: Core1 is an aromatic polycyclic conjugated molecule having two-dimensional flat form and that self-assembles to form supramolecular structures. R1 are electron donor groups connected to Core1 and R1? are electron acceptor groups connected to Corel, m is number of acceptor groups R1, m? is a number of donor groups R?. The numbers m and m? are equal to 0, 1, 2, 3, 4, 5 or 6, but both m and m? are not both equal to 0. R2 is a substituent comprising one or more ionic groups connected to Core1 directly or via a connecting group; a number p of ionic groups R2 is 0, 1, 2, 3 or 4. The fragment marked NLE has a nonlinear effect of polarization. Core2 is a self-assembling electro-conductive oligomer, a number n of the such oligomers is 0, 2, or 4. R3 is a substituent comprising one or more ionic groups connected to Core2; a number s of the ionic groups R3 is 0, 1, 2, 3 or 4.