On the energy transfer in Bi2WO6: ERedOx-assisted radiative recombination in O2 and ROS sensing. prospective

IF 2.2 4区 化学 Q2 Engineering
Oswaldo Núñez, Lorean Madriz, Ronald Vargas
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引用次数: 0

Abstract

Photoluminescence maximum emission signal of colloids based on Bi2WO6 suspended in an aqueous solution is blue-shifted as compared to its band gap according to Eg + (ERedOx-ECB). This process involves the exergonic non-radiative transfer of ECB electron to ERedOx and the concomitant radiative emission of a second electron that has gained ERedOx-ECB energy presumably by electrons energy levels entanglement induced via simultaneous light excitement of multiple electrons. These results constitute evidence for energy transfer with application in sensing electrolyte-electron-acceptors as reactive oxygen species that may be implemented for example in cancer and aortic dissection detection and treatment.

Graphical abstract

Bi2WO6 electrons from water colloidal solution are entangled by light (Plasmon resonance) and excited from the Bi2WO6 valence band (VB) to its conduction band (CB). Electron 1 moves up the gradient at the surface and is transferred to the acceptor (ERedOx) at the electrolyte. The gained energy, ERedOx—ECb, is transferred to electron 2 via their entangled energy levels. Electron 2 then decays to the VB emitting light at the Bi2WO6 band gap (Eg) plus the energy gained. Sensing of the ERedOx and [RedOx] is then obtained.

Abstract Image

Bi2WO6中的能量转移:O2和ROS传感中的ERedOx辅助辐射重组。 展望
根据 Eg + (ERedOx-ECB),悬浮在水溶液中的基于 Bi2WO6 的胶体的光致发光最大发射信号与其带隙相比发生蓝移。这一过程涉及 ECB 电子向 ERedOx 的非辐射性外转移,以及获得 ERedOx-ECB 能量的第二个电子的辐射性发射,这可能是由于多个电子同时受到光激发而引起的电子能级纠缠。这些结果构成了能量转移的证据,可应用于电解质电子受体作为活性氧物种的感应,例如癌症和主动脉夹层的检测和治疗。图解摘要来自水胶体溶液的 Bi2WO6 电子被光纠缠(等离子共振),并从 Bi2WO6 价带 (VB) 激发到其导带 (CB)。电子 1 在表面沿着梯度向上移动,并转移到电解质中的受体(ERedOx)。获得的能量 ERedOx-ECb 通过它们的纠缠能级转移到电子 2。然后,电子 2 在 Bi2WO6 带隙 (Eg) 加上获得的能量衰减为 VB 发光。然后就能感应 ERedOx 和 [RedOx]。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Chemical Papers
Chemical Papers Chemical Engineering-General Chemical Engineering
CiteScore
3.30
自引率
4.50%
发文量
590
期刊介绍: Chemical Papers is a peer-reviewed, international journal devoted to basic and applied chemical research. It has a broad scope covering the chemical sciences, but favors interdisciplinary research and studies that bring chemistry together with other disciplines.
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