碳点的化学诱导荧光开关及其多逻辑门实现

Chemically induced fluorescence switching of carbon-dots and its multiple logic gate implementation.

作者信息

Dhenadhayalan Namasivayam, Lin King-Chuen

机构信息

Department of Chemistry, National Taiwan University, and Institute of Atomic and Molecular Sciences, Academia Sinica, Taipei 106, Taiwan.

出版信息

Sci Rep. 2015 May 6;5:10012. doi: 10.1038/srep10012.

DOI:10.1038/srep10012

PMID:25943914

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4650751/

Abstract

Investigations were carried out on the carbon-dots (C-dots) based fluorescent off - on (Fe(3 + )- S2O3(2-)) and on - off (Zn(2 + )- PO4(3-)) sensors for the detection of metal ions and anions. The sensor system exhibits excellent selectivity and sensitivity towards the detection of biologically important Fe(3 + ), Zn(2 + ) metal ions and S2O3(2-), PO4(3-) anions. It was found that the functional group on the C-dots surface plays crucial role in metal ions and anions detection. Inspired by the sensing results, we demonstrate C-dots based molecular logic gates operation using metal ions and anions as the chemical input. Herein, YES, NOT, OR, XOR and IMPLICATION (IMP) logic gates were constructed based on the selection of metal ions and anions as inputs. This carbon-dots sensor can be utilized as various logic gates at the molecular level and it will show better applicability for the next generation of molecular logic gates. Their promising properties of C-dots may open up a new paradigm for establishing the chemical logic gates via fluorescent chemosensors.

摘要

对基于碳点（C点）的荧光开-关（Fe(3 +)-S2O3(2-)）和关-开（Zn(2 +)-PO4(3-)）传感器进行了研究，用于检测金属离子和阴离子。该传感器系统对检测具有生物学重要性的Fe(3 +)、Zn(2 +)金属离子以及S2O3(2-)、PO4(3-)阴离子表现出优异的选择性和灵敏度。研究发现，C点表面的官能团在金属离子和阴离子检测中起关键作用。受传感结果启发，我们展示了以金属离子和阴离子作为化学输入的基于C点的分子逻辑门操作。在此，基于选择金属离子和阴离子作为输入构建了“是”（YES）、“非”（NOT）、“或”（OR）、“异或”（XOR）和“蕴含”（IMP）逻辑门。这种碳点传感器可在分子水平用作各种逻辑门，并且对下一代分子逻辑门将显示出更好的适用性。C点的这些有前景的特性可能为通过荧光化学传感器建立化学逻辑门开辟新的范例。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c926/4650751/70591b187d28/srep10012-f1.jpg

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碳点的化学诱导荧光开关及其多逻辑门实现

Chemically induced fluorescence switching of carbon-dots and its multiple logic gate implementation.

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