Stimulated Raman imaging below the diffraction limit with a MHz laser

激光器 拉曼光谱 光学 激光功率缩放 信号(编程语言) 材料科学 衍射 脉搏(音乐) 拉曼散射 脉冲持续时间 分辨率(逻辑) 化学 光电子学 物理 计算机科学 探测器 人工智能 程序设计语言
作者
Christian T. Graefe,David Punihaole,Michael J. Lynch,W. Ruchira Silva,Renee R. Frontiera
出处
期刊:Journal of Raman Spectroscopy [Wiley]
卷期号:52 (2): 404-411 被引量:6
标识
DOI:10.1002/jrs.5970
摘要

Abstract Super‐resolution techniques based on Raman spectroscopy could be implemented as label‐free alternatives to fluorescence‐based techniques due to their chemically specific signal and multiplexing potential. In previous work, we developed a stimulated Raman‐based imaging technique that surpassed the diffraction limit using a toroidally shaped pulse to deplete the signal in a spatially defined area. The photophysical principles of depletion and improved spatial resolution were demonstrated using a 1‐kHz laser with high peak power that were able to efficiently drive depletion. However, this laser was not well suited for soft matter samples, which degraded under the intense beams. To improve the biological capabilities of our setup, we have adapted our technique for a 2.04‐MHz laser system. The increased repetition rate produces far more spectra per second, allowing us to decrease the pulse powers while maintaining reasonable acquisition times. Using the 2.04‐MHz laser, we are able to demonstrate strong signal depletion of 62% and resolution enhancements of 52%, which is comparable with the metrics obtained with the 1‐kHz laser. However, further improvements in resolution were not achieved despite increases in the depletion beam energy relative to the other beams. Frequency‐resolved optical gating analysis of the fundamental output of the 2.04 MHz laser indicated an inconsistent pulse phase and duration. We expect that the inconsistent depletion was a result of this pulse profile and conclude that efficient depletion depends on highly reproducible and stable laser pulses.
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
热心的善愁完成签到 ,获得积分10
刚刚
1秒前
1秒前
1秒前
萧寒完成签到,获得积分10
2秒前
3秒前
3秒前
负责凛完成签到,获得积分10
4秒前
赘婿应助z12采纳,获得10
4秒前
5秒前
5秒前
萧寒发布了新的文献求助30
5秒前
十文字发布了新的文献求助10
5秒前
5秒前
知名不具发布了新的文献求助10
6秒前
鹿城第一哈基米关注了科研通微信公众号
6秒前
6秒前
Cheish发布了新的文献求助10
8秒前
秋秋发布了新的文献求助50
9秒前
华仔应助十文字采纳,获得10
10秒前
orixero应助xiaomaxia采纳,获得10
11秒前
大个应助研友_8WdzPL采纳,获得20
12秒前
Hello应助helix采纳,获得10
12秒前
13秒前
13秒前
很靠近海发布了新的文献求助10
14秒前
14秒前
ding应助如意巨人采纳,获得10
14秒前
17秒前
领导范儿应助淡然语芙采纳,获得10
17秒前
CipherSage应助埃维采纳,获得20
17秒前
18秒前
18秒前
19秒前
20秒前
小蘑菇应助研友_8WdzPL采纳,获得10
20秒前
王大强发布了新的文献求助10
21秒前
小二郎应助潇洒迎海采纳,获得10
22秒前
Paddi完成签到 ,获得积分10
22秒前
王特发布了新的文献求助10
22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
Molecular Mechanisms of Photosynthesis, 4th Edition 1000
Organic Reactions, Volume 116 1000
Matrix Methods in Data Mining and Pattern Recognition 510
Reading and Understanding Health Research 500
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 7252157
求助须知:如何正确求助?哪些是违规求助? 8874563
关于积分的说明 18732705
捐赠科研通 6932196
什么是DOI,文献DOI怎么找? 3199633
关于科研通互助平台的介绍 2374362
邀请新用户注册赠送积分活动 2174231