Anthraimidazoledione-Terpyridine-Based Optical Chemosensor for Anions and Cations That Works As Molecular Half-Subtractor, Key-Pad Lock, and Memory Device

Mondal, Debiprasad; Bar, Manoranjan; Maity, Dinesh; Baitalik, Sujoy

doi:10.1021/acs.jpcc.5b08337

Cited by 54 publications

(30 citation statements)

References 69 publications

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“…Thus, from the above observation, a sequential logic circuit i.e. memory device which displays -write-read-erase-read‖ sequences in the form of binary logic function can be constructed [82].…”

Section: Molecular Logic Gatesmentioning

confidence: 99%

A ratiometric chemosensor for Al3+ based on naphthalene-quinoline conjugate with the resultant complex as secondary sensor for F−: Interpretation of molecular logic gates

Roy

Dey

Roy

2016

Sensors and Actuators B: Chemical

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Section: Molecular Logic Gatesmentioning

confidence: 99%

A ratiometric chemosensor for Al3+ based on naphthalene-quinoline conjugate with the resultant complex as secondary sensor for F−: Interpretation of molecular logic gates

Roy

Dey

Roy

2016

Sensors and Actuators B: Chemical

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“…Now, for the purpose of manufacturing memory devices that are capable of storing information and information processing at the molecular level, the reversible and reproducible fluorescence switching process of CZ could be employed to design a useful sequential logic circuit displaying “Erase‐Read‐Write‐Read” behaviour in the form of binary logic. Memory devices operate through feedback loop where one of the outputs serves as input and is memorized as a “memory element” ,. Thus, based on the above principle we were able to design a sequential logic circuit displaying “Erase‐Read‐Write‐Read” with the help of binary logic employing on CZ as device (Figure ).…”

Section: Resultsmentioning

confidence: 99%

Multifunctional Logic Applications of a Single Molecule: A Molecular Photo‐Switch Performing as Simple and Complex Gates, Memory Element, and a Molecular Keypad Lock

Karar

Shit

Halder³

et al. 2018

ChemistrySelect

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Carbazole (CZ) can act as a photo‐switch leading to a multifunctional logic system when triggered by fluoride (F–) ions, H2O and light, through efficient interaction of the pyrrole unit with the anions. Here we are reporting a unimolecular platform of CZ (and case specific CZ‐F–) that can be configured as NOT, YES, complimentary IMPLICATION and INHIBIT, a new complex logic gate performing IF‐THEN and NOT operations and a memory element with cyclic “Erase‐Read‐Write‐Read” ability with feedback loop mechanism. The fluorescence responses of the CZ system also have been exploited to design a potential highly secured molecular keypad lock operating with a purely opto‐chemical password composed with optical and chemical input keys. The system displays the applications of light responsive molecules as multifunctional, reconfigurable molecular logic devices that may lead towards true molecular information processing units.

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“…The latter are macroscopic analytical devices that, similar to the way the olfactory system operates, can interact non‐specifically with a wide range of analytes and discriminate among them by creating a wide range of unique identification patterns . Hence, the main difference between 8 and the molecular keypad locks discussed before is that instead of generating a single digital output (0 or 1) for each code entry, it associates each password with a unique emission “signature” that enables it to authorize multiple users.…”

Section: User Authorization By Pattern‐generating Fluorescent Molecumentioning

confidence: 99%

User Authorization at the Molecular Scale

2017

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Electronic user authorization systems help us maintain our privacy in many aspects of everyday life. However, the increasing difficulty to secure access and/or information digitally has inspired chemists to devise alternative, molecular approaches, in which users are identified by chemical means. The potential advantages of using molecular user authentication systems over conventional electronic devices are their versatility and unusual operating principles, which complicate replicating and, consequently, breaking into molecular security devices. Their molecular scale is another unique property that enables hiding such systems and, consequently, applying steganography as an additional layer of protection. Although the area of molecular‐based user authorization is still in its infancy, the development of various molecular keypad locks and, more recently, a password‐protected molecular cryptographic machine, indicate the possibility of protecting information at the molecular scale.

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Anthraimidazoledione-Terpyridine-Based Optical Chemosensor for Anions and Cations That Works As Molecular Half-Subtractor, Key-Pad Lock, and Memory Device

Cited by 54 publications

References 69 publications

A ratiometric chemosensor for Al3+ based on naphthalene-quinoline conjugate with the resultant complex as secondary sensor for F−: Interpretation of molecular logic gates

A ratiometric chemosensor for Al3+ based on naphthalene-quinoline conjugate with the resultant complex as secondary sensor for F−: Interpretation of molecular logic gates

Multifunctional Logic Applications of a Single Molecule: A Molecular Photo‐Switch Performing as Simple and Complex Gates, Memory Element, and a Molecular Keypad Lock

User Authorization at the Molecular Scale

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