A molecular keypad lock with 3-output signals built on stimulus-responsive polymer film electrodes containing diallyl viologen

Herein, by a one-step synthetization method, a viologen derivative diallyl viologen (DAV) was first poly-merized with methacryloylglycine (MAG) into P(MAG-DAV) polymer films on the surface of ITO elec-trodes. DAV component in the P(MAG-DAV) films was used not only as a cross-linker and immobilized in the film phase for repetitive usages, but also demonstrated reversibly electrochromic and lumines-cent properties. When the electrode voltage was switched between -0.7 and -0.5 V (vs SCE), DAV could transfer from its purple reduction state (DAV(center dot+)) to colorless oxidation state (DAV(2+)) through the electrode reactions, accompanied with the fluorescence signal switching between non-fluorescence (DAV(center dot+)) and green fluorescence (DAV2+) states. The addition of KMnO4 in the solution could oxidize DAV(center dot+) to its DAV(2+) form in the films to generate electrocatalytic signals and change the optical signals at the same time. Based on various reversible stimulus-responsive behaviors of P(MAG-DAV) film electrodes, a logic system of 3-input/3-output was established using potential, KMnO4 and ultraviolet excitation light as in-puts, and cyclic voltammetry (CV), fluorescence (FL) and UV -vis signals as outputs. Including an encoder and a decoder, a unique resettable and reprogrammable keypad lock was built with 3 different outputs. The system used a single immobilized molecule as the core of computing, and applied only 3 stimuli as inputs to construct an integrated logic computing system with 3 different output signals, which greatly improved the complexity and diversity of the molecular computing system. This might provide a new idea for the subsequent development of multifunctional integrated logic devices. (C) 2022 Elsevier Ltd. All rights reserved.

Automated summary

In this study, P(MAG-DAV) polymer films were synthesized on ITO electrodes using a one-step method, and exhibited reversible electrochromic and luminescent properties. Based on these reversible stimulus-responsive behaviors, a logic system with 3 inputs/3 outputs was constructed, and a resettable and reprogrammable keypad lock was successfully realized.