Supramolecular chirality in redox metallopolymers

What is claimed is: 1 . An optically active polymer comprising repeating units represented by formula I, II or III: wherein, when present, C* is a chiral carbon atom having a stereospecific configuration that is the same for at least 90% of the repeating units; J is —(CH 2 ) x — wherein x is 2, 3, or 4; M is a transition metal or transition metal ion; R 1 is alkyl; R 2 , R 3 , R 4 , and R 5 are each independently H or alkyl; R 6 is an optically active moiety wherein the moiety is an amino acid, tertiary polypeptide, saccharide, or antibiotic, and at least 90% of R 6 are the same optical isomers; Z 1 and Z 2 are each independently a terminating group or a polymer block; k and m are each independently an integer from 1-1000; and n is an integer from 10 to 1000. 2 . The optically active polymer of claim 1 wherein the transition metal is iron or an iron ion. 3 . The optically active polymer of claim 1 wherein the optically active polymer comprises poly(N-1-ferrocenyl ethylmethacrylamide). 4 . The optically active polymer of claim 1 wherein the optically active polymer comprises 2-((1-ferrocenylethyl)(methyl)amino)ethyl methacrylate. 5 . The optically active polymer of claim 1 wherein the optically active polymer is represented by formula I or II and the chiral carbon atom (C*) has an (S)-configuration, or wherein the optically active polymer is represented by formula III and the optical rotation of R 6 is levorotatory. 6 . The optically active polymer of claim 1 wherein the optically active polymer is represented by formula I or II and the chiral carbon atom (C*) has an (R)-configuration, or wherein the optically active polymer is represented by formula III and the optical rotation of R 6 is dextrorotatory. 7 . The optically active polymer of claim 1 wherein the optically active polymer is crosslinked or is a block of a copolymer. 8 . A chiral electrode comprising an optically active polymer according to claim 1 wherein the optically active polymer is immobilized on a current collector. 9 . The chiral electrode of claim 8 further comprising mesoporous carbon, or a carbon allotrope or carbon nanotube, that is immobilized on the chiral electrode. 10 . A chiral electrode comprising: an optically active polymer, comprising repeating units, immobilized on a current collector, wherein one or more of the repeating units comprise a redox active moiety and an optically active moiety; wherein at least 90% of all optically active moieties of the optically active polymer are the same optical isomer. 11 . The chiral electrode of claim 10 wherein the redox active moiety comprises a metallocene. 12 . The chiral electrode of claim 10 wherein the optically active moiety comprises a nitrogen atom covalently bonded directly to a chiral carbon atom, or the optically active moiety comprises an amino acid, tertiary polypeptide, saccharide, or antibiotic. 13 . The chiral electrode of claim 10 wherein the repeating unit comprises an acrylate that forms the backbone of the optically active polymer. 14 . The chiral electrode of claim 10 wherein the optically active polymer comprises about 10 to about 1000 repeating units. 15 . An electrochemical method for sensing or separating and optical isomer, comprising: a) contacting a solution comprising a mixture of optical isomers and a chiral electrode according to claim 8 ; and b) applying a voltage potential to the chiral electrode wherein the voltage potential is applied under suitable conditions for chronoamperometry or voltammetry; c1) sensing a preferred optical isomer in the mixture via a change in voltage, current, or impedance relative to a reference; and/or c2) separating from the mixture the preferred optical isomer; wherein the chiral electrode is the working electrode in an electrochemical cell and an optically active moiety of the optically active polymer selectively binds to the preferred optical isomer in the mixture thereby sensing the preferred optical isomer in the mixture or separating the preferred optical isomer from the mixture. 16 . The method of claim 15 wherein the applied voltage potential is sufficient to oxidize or reduce the optically active polymer. 17 . The method of claim 15 wherein the applied voltage potential is applied across a voltage range is sufficient to oxidize or reduce the optically active polymer. 18 . The method of a claim 15 wherein the solution is a supersaturated mixture of optical isomers. 19 . The method of claim 15 further comprising inducing nucleation and crystallization of the preferred optical isomer on the chiral electrode. 20 . The method of claim 15 further comprising desorbing the preferred optical isomer to provide a separated optical isomer that is optically active.