Rational Design of Reversible Redox Shuttle for Highly Efficient Light-Driven Microswimmer

Jizhuang Wang; Ze Xiong; Ming Liu; Xiao-meng Li; Jing Zheng; Xiaojun Zhan; Weiting Ding; Jianan Chen; Xuechen Li; Xiang David Li; Shien-Ping Feng; Jinyao Tang

doi:10.1021/acsnano.9b08799

Rational Design of Reversible Redox Shuttle for Highly Efficient Light-Driven Microswimmer

Jizhuang Wang, Ze Xiong^*, Ming Liu, Xiao-meng Li, Jing Zheng, Xiaojun Zhan, Weiting Ding, Jianan Chen, Xuechen Li, Xiang David Li, Shien-Ping Feng, Jinyao Tang^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

35 Citations (Scopus)

Abstract

The light-driven micro/nanomotor (LMNM) is machinery that harvests photon energy and generates self-propulsion in varieties of liquid media. Though visions are made that these tiny swimming machines can serve future medicine for accurate drug delivery and noninvasive microsurgery, their biomedical application is still impeded by the insufficient propulsion efficiency. Here we provide a holistic model of LMNM by considering (i) photovoltaic, (ii) electrochemical, and (iii) electrokinetic processes therein. Such a quantitative model revealed the pivotal role of reaction kinetics and diffusion properties of shuttle ions in the propulsion efficiency of LMNM. With the guidance of this model, a group of ferrocene-based reversible redox shuttles, which generate slow-diffusion ions, was identified, showcasing a high locomotion velocity of ∼500 μm/s (∼100 body length per second) at an ultralow concentration (70 μM). Owing to the in-depth understanding of the fundamental energy conversion processes in LMNM, we anticipate that the development of other high-performance supporting chemicals and LMNM systems will be greatly motivated, foreseeing the advent of LMNM systems with superior efficiency.

Original language	English
Pages (from-to)	3272-3280
Journal	ACS Nano
Volume	14
Issue number	3
Online published	3 Mar 2020
DOIs	https://doi.org/10.1021/acsnano.9b08799
Publication status	Published - 24 Mar 2020
Externally published	Yes

Research Keywords

biocompatibility
efficiency
light-driven microswimmer
redox shuttles
silicon nanowire

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access Output

10.1021/acsnano.9b08799

Other Access Options

Check CityUHK Library

Permanent Link

Right click to copy link

Cite this

@article{f157b112b26f439c95e7394cb2ef1398,

title = "Rational Design of Reversible Redox Shuttle for Highly Efficient Light-Driven Microswimmer",

abstract = "The light-driven micro/nanomotor (LMNM) is machinery that harvests photon energy and generates self-propulsion in varieties of liquid media. Though visions are made that these tiny swimming machines can serve future medicine for accurate drug delivery and noninvasive microsurgery, their biomedical application is still impeded by the insufficient propulsion efficiency. Here we provide a holistic model of LMNM by considering (i) photovoltaic, (ii) electrochemical, and (iii) electrokinetic processes therein. Such a quantitative model revealed the pivotal role of reaction kinetics and diffusion properties of shuttle ions in the propulsion efficiency of LMNM. With the guidance of this model, a group of ferrocene-based reversible redox shuttles, which generate slow-diffusion ions, was identified, showcasing a high locomotion velocity of ∼500 μm/s (∼100 body length per second) at an ultralow concentration (70 μM). Owing to the in-depth understanding of the fundamental energy conversion processes in LMNM, we anticipate that the development of other high-performance supporting chemicals and LMNM systems will be greatly motivated, foreseeing the advent of LMNM systems with superior efficiency.",

keywords = "biocompatibility, efficiency, light-driven microswimmer, redox shuttles, silicon nanowire",

author = "Jizhuang Wang and Ze Xiong and Ming Liu and Xiao-meng Li and Jing Zheng and Xiaojun Zhan and Weiting Ding and Jianan Chen and Xuechen Li and Li, {Xiang David} and Shien-Ping Feng and Jinyao Tang",

year = "2020",

month = mar,

day = "24",

doi = "10.1021/acsnano.9b08799",

language = "English",

volume = "14",

pages = "3272--3280",

journal = "ACS Nano",

issn = "1936-0851",

publisher = "American Chemical Society",

number = "3",

}

TY - JOUR

T1 - Rational Design of Reversible Redox Shuttle for Highly Efficient Light-Driven Microswimmer

AU - Wang, Jizhuang

AU - Xiong, Ze

AU - Liu, Ming

AU - Li, Xiao-meng

AU - Zheng, Jing

AU - Zhan, Xiaojun

AU - Ding, Weiting

AU - Chen, Jianan

AU - Li, Xuechen

AU - Li, Xiang David

AU - Feng, Shien-Ping

AU - Tang, Jinyao

PY - 2020/3/24

Y1 - 2020/3/24

N2 - The light-driven micro/nanomotor (LMNM) is machinery that harvests photon energy and generates self-propulsion in varieties of liquid media. Though visions are made that these tiny swimming machines can serve future medicine for accurate drug delivery and noninvasive microsurgery, their biomedical application is still impeded by the insufficient propulsion efficiency. Here we provide a holistic model of LMNM by considering (i) photovoltaic, (ii) electrochemical, and (iii) electrokinetic processes therein. Such a quantitative model revealed the pivotal role of reaction kinetics and diffusion properties of shuttle ions in the propulsion efficiency of LMNM. With the guidance of this model, a group of ferrocene-based reversible redox shuttles, which generate slow-diffusion ions, was identified, showcasing a high locomotion velocity of ∼500 μm/s (∼100 body length per second) at an ultralow concentration (70 μM). Owing to the in-depth understanding of the fundamental energy conversion processes in LMNM, we anticipate that the development of other high-performance supporting chemicals and LMNM systems will be greatly motivated, foreseeing the advent of LMNM systems with superior efficiency.

AB - The light-driven micro/nanomotor (LMNM) is machinery that harvests photon energy and generates self-propulsion in varieties of liquid media. Though visions are made that these tiny swimming machines can serve future medicine for accurate drug delivery and noninvasive microsurgery, their biomedical application is still impeded by the insufficient propulsion efficiency. Here we provide a holistic model of LMNM by considering (i) photovoltaic, (ii) electrochemical, and (iii) electrokinetic processes therein. Such a quantitative model revealed the pivotal role of reaction kinetics and diffusion properties of shuttle ions in the propulsion efficiency of LMNM. With the guidance of this model, a group of ferrocene-based reversible redox shuttles, which generate slow-diffusion ions, was identified, showcasing a high locomotion velocity of ∼500 μm/s (∼100 body length per second) at an ultralow concentration (70 μM). Owing to the in-depth understanding of the fundamental energy conversion processes in LMNM, we anticipate that the development of other high-performance supporting chemicals and LMNM systems will be greatly motivated, foreseeing the advent of LMNM systems with superior efficiency.

KW - biocompatibility

KW - efficiency

KW - light-driven microswimmer

KW - redox shuttles

KW - silicon nanowire

UR - http://www.scopus.com/inward/record.url?scp=85082342048&partnerID=8YFLogxK

UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-85082342048&origin=recordpage

U2 - 10.1021/acsnano.9b08799

DO - 10.1021/acsnano.9b08799

M3 - RGC 21 - Publication in refereed journal

C2 - 32125822

SN - 1936-0851

VL - 14

SP - 3272

EP - 3280

JO - ACS Nano

JF - ACS Nano

IS - 3

ER -

Rational Design of Reversible Redox Shuttle for Highly Efficient Light-Driven Microswimmer

Abstract

Research Keywords

UN SDGs

Access Output

Other Access Options

Permanent Link

Other Files and Links

Fingerprint

Cite this