Water‐Induced Bandgap Engineering in Nanoribbons of Hexagonal Boron Nitride

材料科学 带隙 电场 光电子学 宽禁带半导体 光电流 直接和间接带隙 凝聚态物理 纳米技术 物理 量子力学
作者
Chen Chen,Hang Yang,Hui Shan Wang,Yang Wang,Xiujun Wang,Chengxin Jiang,Yu Feng,Chenxi Liu,Eli Janzen,James H. Edgar,Zhipeng Wei,Wanlin Guo,Weida Hu,Zhuhua Zhang,Haomin Wang,Xiaoming Xie
出处
期刊:Advanced Materials [Wiley]
卷期号:35 (36) 被引量:7
标识
DOI:10.1002/adma.202303198
摘要

Different from hexagonal boron nitride (hBN) sheets, the bandgap of hBN nanoribbons (BNNRs) can be changed by spatial/electrostatic confinement. It is predicted that a transverse electric field can narrow the bandgap and even cause an insulator-metal transition in BNNRs. However, experimentally introducing an overhigh electric field across the BNNR remains challenging. Here, it is theoretically and experimentally demonstrated that water adsorption greatly reduces the bandgap of zigzag-oriented BNNRs (zBNNRs). Ab initio calculations show that water molecules can be favorably assembled within the trench between two adjacent BNNRs to form a polar ice layer, which induces a transverse equivalent electric field of over 2 V nm-1 accounting for the bandgap reduction. Field-effect transistors are successfully fabricated from zBNNRs with different widths. The conductance of water-adsorbed zBNNRs can be tuned over 3 orders in magnitude via modulation of the equivalent electrical field at room temperature. Furthermore, photocurrent response measurements are taken to determine the optical bandgaps of zBNNRs with water adsorption. The zBNNR with increased width can exhibit a bandgap down to 1.17 eV. This study offers fundamental insights into new routes toward realizing electronic/optoelectronic devices and circuits based on hexagonal boron nitride.

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
刚刚
罗劲松发布了新的文献求助10
刚刚
1秒前
wanci应助科研通管家采纳,获得10
1秒前
爆米花应助科研通管家采纳,获得10
1秒前
123应助科研通管家采纳,获得10
1秒前
wanci应助科研通管家采纳,获得10
1秒前
无极微光应助科研通管家采纳,获得20
1秒前
小蘑菇应助科研通管家采纳,获得10
1秒前
思源应助科研通管家采纳,获得100
1秒前
Dan_Young应助科研通管家采纳,获得10
1秒前
1秒前
Kao应助科研通管家采纳,获得10
1秒前
科研通AI6.4应助13026581019采纳,获得10
1秒前
1秒前
Ava应助科研通管家采纳,获得10
1秒前
bkagyin应助科研通管家采纳,获得10
2秒前
共享精神应助科研通管家采纳,获得10
2秒前
小蘑菇应助科研通管家采纳,获得10
2秒前
tiptip应助科研通管家采纳,获得30
2秒前
Copyright应助科研通管家采纳,获得10
2秒前
搜集达人应助科研通管家采纳,获得10
2秒前
2秒前
lqm发布了新的文献求助10
2秒前
2秒前
YiDuo应助科研通管家采纳,获得10
2秒前
2秒前
2秒前
2秒前
2秒前
2秒前
3秒前
研究僧完成签到,获得积分10
3秒前
秋暄念发布了新的文献求助10
3秒前
天道酬勤完成签到,获得积分10
3秒前
4秒前
4秒前
多云发布了新的文献求助10
4秒前
小T儿完成签到,获得积分10
5秒前
小跳鹅完成签到,获得积分10
5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
Organic Reactions, Volume 116 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
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 7278823
求助须知:如何正确求助?哪些是违规求助? 8899868
关于积分的说明 18823220
捐赠科研通 6950999
什么是DOI,文献DOI怎么找? 3206968
关于科研通互助平台的介绍 2377520
邀请新用户注册赠送积分活动 2181943