Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media

Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media

A mercury sensor (N-(rhodamine-6G)lactam-ethylenediamine-4-dimethylamino-cinnamaldehyde—RLED) based on the Hg2+-promoted hydrolysis reaction has been designed and developed with a combination of theoretical calculations and experimental investigations. The interaction between RLED and Hg2+...

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Main Authors: Mai Van Bay, Nguyen Khoa Hien, Subin Son, Nguyen Duy Trinh, Nguyen Tien Trung, Pham Cam Nam, Jong Seung Kim, Duong Tuan Quang
Format: Article
Language:English
Published: MDPI AG 2019-01-01
Series:Sensors
Subjects:
fluorescence
hydrolysis
rhodamine
quantum chemical calculations
mercury
Online Access:http://www.mdpi.com/1424-8220/19/1/128
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spelling doaj-870ce026313d4694976e701f4c2e2e742020-11-24T21:13:36ZengMDPI AGSensors1424-82202019-01-0119112810.3390/s19010128s19010128Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous MediaMai Van Bay0Nguyen Khoa Hien1Subin Son2Nguyen Duy Trinh3Nguyen Tien Trung4Pham Cam Nam5Jong Seung Kim6Duong Tuan Quang7Department of Chemistry, Hue University, Hue City 84-234, VietnamMientrung Institute for Scientific Research, Vietnam Academy of Science and Technology, Hue City 84-234, VietnamDepartment of Chemistry, Korea University, Seoul 02841, KoreaNTT Hi-Tech Institute, Nguyen Tat Thanh University, Ho Chi Minh City 84-28, VietnamLaboratory of Computational Chemistry and Modelling, Department of Chemistry, Quy Nhon University, Quy Nhon City 84-256, VietnamThe University of Danang (University of Science and Technology), Danang City 84-236, VietnamDepartment of Chemistry, Korea University, Seoul 02841, KoreaDepartment of Chemistry, Hue University, Hue City 84-234, VietnamA mercury sensor (N-(rhodamine-6G)lactam-ethylenediamine-4-dimethylamino-cinnamaldehyde—RLED) based on the Hg2+-promoted hydrolysis reaction has been designed and developed with a combination of theoretical calculations and experimental investigations. The interaction between RLED and Hg2+ goes through a fast-initial stage with formation of a 1:1 complex, followed by a slow hydrolysis process. The formation of durable intermediate complexes is due to quite a long hydrolysis reaction time. As a result, RLED can selectively detect Hg2+ in the presence of other metal ions, with a detection limit of 0.08 μM for the colorimetric method, and of 0.008 μM with the fluorescent method. In addition, the RLED sensor can work in a solution with a small amount of organic solvent, with a wide pH range from 5 to 10. The time-dependent density functional theory has been used for investigations of the excitation and de-excitation processes in RLED, intermediate complexes, and reaction products, thereby clarifying the changes in the fluorescence intensity before and after the RLED interacts with Hg2+ ions.http://www.mdpi.com/1424-8220/19/1/128fluorescencehydrolysisrhodaminequantum chemical calculationsmercury
collection DOAJ
language English
format Article
sources DOAJ
author Mai Van Bay
Nguyen Khoa Hien
Subin Son
Nguyen Duy Trinh
Nguyen Tien Trung
Pham Cam Nam
Jong Seung Kim
Duong Tuan Quang
spellingShingle Mai Van Bay
Nguyen Khoa Hien
Subin Son
Nguyen Duy Trinh
Nguyen Tien Trung
Pham Cam Nam
Jong Seung Kim
Duong Tuan Quang
Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media
Sensors
fluorescence
hydrolysis
rhodamine
quantum chemical calculations
mercury
author_facet Mai Van Bay
Nguyen Khoa Hien
Subin Son
Nguyen Duy Trinh
Nguyen Tien Trung
Pham Cam Nam
Jong Seung Kim
Duong Tuan Quang
author_sort Mai Van Bay
title Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media
title_short Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media
title_full Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media
title_fullStr Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media
title_full_unstemmed Hg2+-Promoted Spirolactam Hydrolysis Reaction: A Design Strategy for the Highly Selective Sensing of Hg2+ over other Metal Ions in Aqueous Media
title_sort hg2+-promoted spirolactam hydrolysis reaction: a design strategy for the highly selective sensing of hg2+ over other metal ions in aqueous media
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2019-01-01
description A mercury sensor (N-(rhodamine-6G)lactam-ethylenediamine-4-dimethylamino-cinnamaldehyde—RLED) based on the Hg2+-promoted hydrolysis reaction has been designed and developed with a combination of theoretical calculations and experimental investigations. The interaction between RLED and Hg2+ goes through a fast-initial stage with formation of a 1:1 complex, followed by a slow hydrolysis process. The formation of durable intermediate complexes is due to quite a long hydrolysis reaction time. As a result, RLED can selectively detect Hg2+ in the presence of other metal ions, with a detection limit of 0.08 μM for the colorimetric method, and of 0.008 μM with the fluorescent method. In addition, the RLED sensor can work in a solution with a small amount of organic solvent, with a wide pH range from 5 to 10. The time-dependent density functional theory has been used for investigations of the excitation and de-excitation processes in RLED, intermediate complexes, and reaction products, thereby clarifying the changes in the fluorescence intensity before and after the RLED interacts with Hg2+ ions.
topic fluorescence
hydrolysis
rhodamine
quantum chemical calculations
mercury
url http://www.mdpi.com/1424-8220/19/1/128
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