Ratchet-based ion pumping membrane systems

What is claimed is: 1 . An ion transport structure ( 110 ) comprising an ion-permeable layer ( 112 ) coupled to at least two contacts ( 122 ), wherein the ion transport structure ( 110 ) is configured to transport ions across the ion-permeable layer ( 112 ) when an input signal frequency is applied to change electric fields within the ion transport structure, resulting in a ratchet-driven ion pump. 2 . The ion transport structure ( 110 ) of claim 1 , wherein the ion transport structure is configured to continuously transport ions using alternating electronic polarization, wherein the ion transport structure ( 110 ) pumps ions with minimized resistance and without using electrochemical reactions or mechanical forces. 3 . The ion transport structure ( 110 ) of claim 1 , wherein the ion-permeable layer comprises a dielectric material, a semiconductor, a polymer, or an ion-selective material. 4 . The ion transport structure ( 110 ) of claim 1 , wherein the contact ( 122 ) is a layer or wire comprised of an electrically conductive material. 5 . The ion transport structure ( 110 ) of claim 1 , wherein a plurality of channels ( 115 ) is disposed through the ion transport structure ( 110 ). 6 . A method of selectively moving one or more types of ions in a solution, said method comprising: a. providing the ion transport structure ( 110 ) of claim 1 : b. placing the ion transport structure ( 110 ) in the solution; and c. choosing an input signal frequency based on a diffusivity of the one or more types of ions in the solution that modulates a spatially asymmetric electric potential distribution to change electric fields within the ion transport structure to optimally transport the one or more types of ions across the ion-permeable layer ( 112 ) in either direction. 7 . The method of claim 6 , wherein the one or more types of ions in the solution are of a same charge type and are transported in opposite directions, resulting in steady state ion pumping. 8 . The method of claim 6 , wherein the one or more types of ions in the solution are of opposite charge types and are transported in the same direction, resulting in steady state ion pumping. 9 . The method of claim 6 , wherein the transport of ions in the solution causes a net flux of water, thereby pumping water across the ion transport structure. 10 . An ion transport structure ( 110 ) comprising a plurality of ion-permeable layers ( 112 ) and a plurality of contacts ( 122 ) forming a stack in which the ion-permeable layers ( 112 ) alternate with the plurality of contacts ( 122 ), wherein the ion transport structure ( 110 ) is configured to transport ions through the stack when an input signal frequency is applied to change electric fields within the ion transport structure, resulting in a ratchet-driven ion pump. 11 . The ion transport structure ( 110 ) of claim 10 , wherein a plurality of channels ( 115 ) is disposed through the stack of alternating layers. 12 . An ion pumping system ( 100 ) comprising: a. an ion transport structure ( 110 ) comprising an ion-permeable layer ( 112 ) and at least two contacts ( 122 ) coupled to the ion-permeable layer ( 112 ); b. a first ion-selective membrane ( 130 ) operatively coupled to the ion transport structure ( 110 ); and c. a second ion-selective membrane ( 135 ) operatively coupled to the ion transport structure ( 110 ); wherein the first ion-selective membrane ( 130 ) and the second ion-selective membrane ( 135 ) are each selective for ions having a specific charge, wherein the ions are transported across the ion transport structure ( 110 ) and the second ion-selective membrane ( 135 ) when an input signal frequency is applied to change electric fields within the ion transport structure, resulting in a ratchet-driven ion pump. 13 . The ion pumping system ( 100 ) of claim 12 , wherein the ion transport structure is configured to continuously transport ions using alternating electronic polarization, wherein the ion transport structure ( 110 ) pumps ions with minimized resistance and without using electrochemical reactions or mechanical forces. 14 . The system ( 100 ) of claim 12 , wherein the first ion-selective membrane is disposed on the ion transport structure and the second ion-selective membrane ( 135 ) is attached to the ion transport structure ( 110 ) such that the second ion-selective membrane ( 135 ) and ion transport structure ( 110 ) are side by side. 15 . The system ( 100 ) of claim 12 , wherein a plurality of channels ( 115 ) is disposed through the ion transport structure ( 110 ). 16 . The system ( 100 ) of claim 15 , wherein the at least two contacts ( 122 ) comprise two sets of interlaced contact fingers, each set connected to different channels, wherein a first set of strips comprising the first ion-selective membrane ( 130 ) is disposed on one set of contact fingers and a second set of strips comprising the second ion-selective membrane ( 135 ) is disposed on the other set of contact fingers such that the strips of the first ion-selective membrane ( 130 ) alternate with the strips of the second ion-selective membrane ( 135 ), wherein each set of contact fingers has a corresponding set of interlaced contact fingers disposed on the second surface ( 116 ) of the ion-permeable substrate and connected to the same channels, thereby forming a paired set, wherein each paired set is connected to its own separate power source. 17 . A deionization system for moving ions in a solution from a first compartment to a second compartment, comprising the ion pumping system ( 100 ) of claim 12 , wherein the ion pumping system separates the first and second compartment, wherein each compartment contains the solution having an initial concentration of ions, wherein when an input signal frequency is applied to change electric fields within the ion transport structure, resulting in a ratchet mechanism, ions from the first compartment are selectively transported in one direction across the ion pumping system, thereby increasing the ion concentration in the second compartment and reducing the ion concentration in the first compartment. 18 . The deionization system of claim 17 , wherein the first ion selective membrane ( 130 ) is disposed on the ion transport structure ( 110 ) and the second ion-selective membrane ( 135 ) is attached to the ion transport structure ( 110 ) to form a single, continuous barrier that separates the first and second compartment. 19 . The deionization system of claim 17 , wherein the first ion selective membrane ( 130 ) is disposed on the ion transport structure ( 110 ), wherein the second ion-selective membrane ( 135 ) and the ion transport structure ( 110 ) are disconnected, and each one forms a barrier that separates the first and second compartment.