Laser-Assisted Synthesis of Monolayer 2D MoSe2 Crystals with Tunable Vacancy Concentrations: Implications for Gas and Biosensing

单层 空位缺陷 材料科学 光致发光 拉曼光谱 汽化 激光器 纳米技术 激光功率缩放 光电子学 化学物理 分析化学(期刊) 光学 化学 结晶学 有机化学 物理
作者
Nurul Azam,Matthew G. Boebinger,Suman Jaiswal,Raymond R. Unocic,Parvin Fathi-Hafshejani,Masoud Mahjouri‐Samani
出处
期刊:ACS applied nano materials [American Chemical Society]
卷期号:5 (7): 9129-9139 被引量:14
标识
DOI:10.1021/acsanm.2c01458
摘要

We report tuning the structural and electronic properties of atomically thin two-dimensional (2D) materials via defect and vacancy engineering is the key to enabling their potential use in various applications, including electronics, energy, and sensing devices. Vacancies are, for instance, becoming highly promising for the enhanced interaction of gases and biomolecules with 2D materials in energy and sensing applications. However, the deterministic generation of desirable vacancies with tunable concentrations remains a challenge in 2D materials due to the limitations in the current growth methods, such as the complex reaction chemistries and gas flow dynamics. Therefore, engineering defects and vacancies in 2D materials have been mainly limited to destructive top-down processes such as heating, ion bombardments, and laser postprocessing. Here, we introduce a single-step bottom-up synthesis approach for the growth of monolayer MoSe<sub>2</sub> crystals with tunable vacancy concentrations. This method utilizes the spatiotemporal properties and adjustable power densities of the lasers to control the vaporization dynamics of the stoichiometric MoSe<sub>2</sub> powders. Such a mechanism in the vaporization allows us to grow tunable stoichiometry monolayer MoSe<sub>2–x</sub> crystals on the substrates. The localized and time-controlled (250 ms to 2 s) vaporization of the MoSe<sub>2</sub> powder by a CO<sub>2</sub> laser enables the formation of monolayer crystals with controlled vacancy concentrations ranging from ~1 to 20%. The effects of laser power, laser irradiation time, and background pressure on the tuning range and subsequent properties of the crystals are investigated and quantified using Raman and photoluminescence spectroscopy, scanning transmission electron microscopy (STEM), and time-correlated single-photon counting (TCSPC). This bottom-up synthesis is a promising approach that allows the deterministic vacancy tuning for future electronics and, in particular, gas and biosensing applications without the need for further postprocessing and potential structural disruption of the crystals.
最长约 10秒,即可获得该文献文件

科研通智能强力驱动
Strongly Powered by AbleSci AI
科研通是完全免费的文献互助平台,具备全网最快的应助速度,最高的求助完成率。 对每一个文献求助,科研通都将尽心尽力,给求助人一个满意的交代。
实时播报
刻苦的砖头完成签到,获得积分10
1秒前
蜜獾完成签到,获得积分10
1秒前
1秒前
1秒前
送风管道发布了新的文献求助30
1秒前
hrpppp发布了新的文献求助10
1秒前
3秒前
科研通AI6.4应助wangyuan采纳,获得10
4秒前
Hello应助xmn采纳,获得10
4秒前
愉快书琴完成签到 ,获得积分10
4秒前
rico发布了新的文献求助10
4秒前
maxwell完成签到,获得积分10
4秒前
Aisha完成签到,获得积分10
5秒前
清秀的金鱼举报李青秀求助涉嫌违规
5秒前
5秒前
gj12345完成签到,获得积分20
5秒前
小马甲应助小点点cy_采纳,获得10
6秒前
wp完成签到,获得积分10
6秒前
6秒前
叨叨小夫夫完成签到,获得积分10
6秒前
Nexus应助嘟嘟采纳,获得40
7秒前
orixero应助科研通管家采纳,获得10
8秒前
9秒前
所所应助xiaoxing采纳,获得10
9秒前
林金花应助科研通管家采纳,获得10
9秒前
共享精神应助科研通管家采纳,获得10
9秒前
cc应助科研通管家采纳,获得10
9秒前
SciGPT应助科研通管家采纳,获得10
9秒前
CodeCraft应助科研通管家采纳,获得10
9秒前
9秒前
田様应助科研通管家采纳,获得10
9秒前
sagitar应助科研通管家采纳,获得20
9秒前
10秒前
Owen应助来看文献采纳,获得10
10秒前
共享精神应助英勇的灯泡采纳,获得10
13秒前
今明源之昨后完成签到,获得积分10
13秒前
迅速靖仇完成签到,获得积分10
14秒前
2052669099发布了新的文献求助100
15秒前
顾矜应助奋斗的橘子采纳,获得10
16秒前
19秒前
高分求助中
Principles of Economics, 11th Edition 10000
University Physics with Modern Physics, 16th edition 10000
(应助此贴封号)【重要!!请各用户(尤其是新用户)详细阅读】【科研通的精品贴汇总】 10000
Development of a Bridge Weigh-In-Motion System: A technology to convert the bridge response to the passage of traffic into data on vehicle configurations, speeds, times of travel and weights 1000
Current concepts in cutaneous toxicity : proceedings of the Fourth Conference on Cutaneous Toxicity, Washington, D.C., May 9-11, 1979 1000
ズームレンズの光学設計に関する研究 800
Fundamentals of Pharmaceutical and Biologics Regulations: A Global Perspective, Second Edition 700
热门求助领域 (近24小时)
化学 材料科学 医学 生物 纳米技术 工程类 有机化学 化学工程 生物化学 计算机科学 内科学 物理 复合材料 催化作用 细胞生物学 无机化学 光电子学 物理化学 电极 基因
热门帖子
关注 科研通微信公众号,转发送积分 7279571
求助须知:如何正确求助?哪些是违规求助? 8900743
关于积分的说明 18826668
捐赠科研通 6951629
什么是DOI,文献DOI怎么找? 3207227
关于科研通互助平台的介绍 2377539
邀请新用户注册赠送积分活动 2182205