An integrated optical waveguide micro-cantilever system for chip-based AFM

被引：0

作者：

Tang, Xinxin ^{[1
]}

Fan, Guofang ^{[1
]}

Zhang, Hongru ^{[1
]}

Dai, Xingang ^{[1
]}

Hu, Yanjun ^{[1
]}

Zhang, Zhiping ^{[3
]}

Li, Yuan ^{[2
]}

机构：

[1] Beijing Jiaotong Univ, Inst Lightwave Technol, Key Lab All Opt Network & Adv Telecommun Network, Minist Educ, Beijing 100044, Peoples R China

[2] Natl Ctr Testing Technol, Natl Ctr Measurement & Testing East China, Shanghai Inst Measurement & Testing Technol, Shanghai, Peoples R China

[3] Fudan Univ, Acad Engn & Technol, Shanghai, Peoples R China

来源：

JOURNAL OF MICROSCOPY | 2022年 / 285卷 / 02期

基金：

国家重点研发计划;

关键词：

atomic force microscopy (AFM); chip-based; integrated optical waveguide cantilever system; nano-tip; ATOMIC-FORCE MICROSCOPY; DESIGN;

D O I：

10.1111/jmi.13080

中图分类号：

TH742 [显微镜];

学科分类号：

摘要：

An optical waveguide cantilever system with a tip is introduced as the displacement detection system of chip-based atomic force microscopy (AFM) system. A chip-based AFM on optical waveguide is demonstrated with sensitivity of up to 4.0 x 10(-2) nm(-1), which is mainly constructed by a 210 nm thick optical waveguide cantilever with a nano-tip. The nano-tip is a height of 1.2 mu m and diameter of 140 nm. This integrated on-chip system provides a displacement range of approximately +/- 0.4 mu m, which makes it possible for the device to be used for AFM imaging and pays the way for further performance improvement.

引用

页码：112 / 116

页数：5

共 50 条

[41] Chip-Based Optical Frequency Combs
Gaeta, A. L.
2017 CONFERENCE ON LASERS AND ELECTRO-OPTICS (CLEO), 2017,
[42] Stiffness Measurement of Micro-Cantilever Based on Negative Electrostatic Stiffness
Dong, Xianshan
Huang, Qinwen
Huang, Yun
Su, Wei
Lai, Ping
NANOSCIENCE AND NANOTECHNOLOGY LETTERS, 2020, 12 (01) : 96 - 100
[43] A micro-cantilever sensor chip based on contact angle analysis for a label-free troponin I immunoassay
Yin, Tsung-I
Zhao, Yunpeng
Horak, Josef
Bakirci, Huseyin
Liao, Hsin-Hao
Tsai, Hann-Huei
Juang, Ying-Zong
Urban, Gerald
LAB ON A CHIP, 2013, 13 (05) : 834 - 842
[44] Low-voltage micromechanical RF switch based on a piezoelectric micro-cantilever integrated with a transmission line
Hyun Woo Yu
Jong-Man Kim
Journal of the Korean Physical Society, 2015, 67 : 1942 - 1946
[45] Analysis of recombinant adenoviruses using an integrated microfluidic chip-based system
McCaman, MT
Murakami, P
Pungor, E
Hahnenberger, KM
Hancock, WS
ANALYTICAL BIOCHEMISTRY, 2001, 291 (02) : 262 - 268
[46] Low-voltage micromechanical RF switch based on a piezoelectric micro-cantilever integrated with a transmission line
Yu, Hyun Woo
Kim, Jong-Man
JOURNAL OF THE KOREAN PHYSICAL SOCIETY, 2015, 67 (11) : 1942 - 1946
[47] An iterative method for nonlinear dynamical system of an electrostatically actuated micro-cantilever
Chen, Y. M.
Meng, G.
Liu, J. K.
PHYSICS LETTERS A, 2010, 374 (34) : 3455 - 3459
[48] Period doubling of the nonlinear dynamical system of an electrostatically actuated micro-cantilever
Chen, Y. M.
Liu, J. K.
SMART STRUCTURES AND SYSTEMS, 2014, 14 (05) : 743 - 763
[49] Integrated three-dimensional optical MEMS for chip-based fluorescence detection
Hung, Kuo-Yung
Tseng, Fan-Gang
Khoo, Hwa-Seng
JOURNAL OF MICROMECHANICS AND MICROENGINEERING, 2009, 19 (04)
[50] Observation of spin-flop transition in antiferromagnetic organic molecular conductors using AFM micro-cantilever
Tokumoto, M
Tanaka, H
Otsuka, T
Kobayashi, H
Kobayashi, A
POLYHEDRON, 2005, 24 (16-17) : 2793 - 2795

← 1 2 3 4 5 →