TY - GEN
T1 - Simultaneous topography imaging and broadband nanomechanical property mapping using atomic force microscope
AU - Li, Tianwei
AU - Zou, Qingze
N1 - Funding Information:
This work was supported by NSF grant CMMI-1200557 and NSF grant DBI-1353890
Publisher Copyright:
© 2017 American Automatic Control Council (AACC).
PY - 2017/6/29
Y1 - 2017/6/29
N2 - In this paper, an approach is proposed to integrate contact-mode imaging with simultaneous broadband nanomechanical property mapping of soft materials in air by using atomic force microscope(AFM). Simultaneous imaging and nanomechanical mapping is needed to correlate the morphological and mechanical evolutions of the sample during the dynamic phenomena such as cell defusion process. However, current method to mechanical property mapping - The force-volume mapping technique - is limited to static elasticity mapping only, whereas the mechanical properties of soft materials are viscoelastic of frequency-dependence in nature. The proposed approach aims to address these challenges to enable simultaneous imaging and broadband nanomechanical mapping of soft materials in air. Specifically, it is proposed to augment a complex excitation input to the sample topography tracking during the imaging process. The proposed approach is illustrated through experimental implementation on a PDMS sample. The experimental results obtained demonstrate that by using the proposed technique, both topography imaging and broadband viscoelasticity quantification can be reliably achieved.
AB - In this paper, an approach is proposed to integrate contact-mode imaging with simultaneous broadband nanomechanical property mapping of soft materials in air by using atomic force microscope(AFM). Simultaneous imaging and nanomechanical mapping is needed to correlate the morphological and mechanical evolutions of the sample during the dynamic phenomena such as cell defusion process. However, current method to mechanical property mapping - The force-volume mapping technique - is limited to static elasticity mapping only, whereas the mechanical properties of soft materials are viscoelastic of frequency-dependence in nature. The proposed approach aims to address these challenges to enable simultaneous imaging and broadband nanomechanical mapping of soft materials in air. Specifically, it is proposed to augment a complex excitation input to the sample topography tracking during the imaging process. The proposed approach is illustrated through experimental implementation on a PDMS sample. The experimental results obtained demonstrate that by using the proposed technique, both topography imaging and broadband viscoelasticity quantification can be reliably achieved.
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U2 - 10.23919/ACC.2017.7963050
DO - 10.23919/ACC.2017.7963050
M3 - Conference contribution
AN - SCOPUS:85027001396
T3 - Proceedings of the American Control Conference
SP - 795
EP - 800
BT - 2017 American Control Conference, ACC 2017
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2017 American Control Conference, ACC 2017
Y2 - 24 May 2017 through 26 May 2017
ER -