Low-volume liquid delivery and nanolithography using a nanopipette combined with a quartz tuning fork-atomic force microscope

Sangmin An; Corey Stambaugh; Gunn Kim; Manhee Lee; Yonghee Kim; Kunyoung Lee; Wonho Jhe

doi:10.1039/c2nr30972f

Low-volume liquid delivery and nanolithography using a nanopipette combined with a quartz tuning fork-atomic force microscope

Sangmin An
, Corey Stambaugh
, Gunn Kim
, Manhee Lee
, Yonghee Kim
, Kunyoung Lee
, Wonho Jhe^*

^*Corresponding author for this work

Department of Physics

Seoul National University
National Institute of Standards and Technology
Sejong University
Harvard University

Research output: Contribution to journal › Journal article › peer-review

32 Scopus citations

Abstract

Electric-field-induced low-volume liquid ejection under ambient conditions was realized at a low bias potential of 12 V via a nanopipette (aperture diameter of 30 nm) combined with a non-contact, distance-regulated (within 10 nm) quartz tuning fork-atomic force microscope. A capillary-condensed water meniscus, spontaneously formed in the tip-substrate nanogap, reduces the ejection barrier by four orders of magnitude, facilitating nanoliquid ejection and subsequent liquid transport/dispersion onto the substrate without contact damage from the pipette. A study of nanofluidics through a free-standing liquid nanochannel and nanolithography was performed with this technique. This is an important breakthrough for various applications in controlled nanomaterial-delivery and selective deposition, such as multicolor nanopatterning and nano-inkjet devices.

Original language	English
Pages (from-to)	6493-6500
Number of pages	8
Journal	Nanoscale
Volume	4
Issue number	20
DOIs	https://doi.org/10.1039/c2nr30972f
State	Published - 2012.10.21

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title = "Low-volume liquid delivery and nanolithography using a nanopipette combined with a quartz tuning fork-atomic force microscope",

abstract = "Electric-field-induced low-volume liquid ejection under ambient conditions was realized at a low bias potential of 12 V via a nanopipette (aperture diameter of 30 nm) combined with a non-contact, distance-regulated (within 10 nm) quartz tuning fork-atomic force microscope. A capillary-condensed water meniscus, spontaneously formed in the tip-substrate nanogap, reduces the ejection barrier by four orders of magnitude, facilitating nanoliquid ejection and subsequent liquid transport/dispersion onto the substrate without contact damage from the pipette. A study of nanofluidics through a free-standing liquid nanochannel and nanolithography was performed with this technique. This is an important breakthrough for various applications in controlled nanomaterial-delivery and selective deposition, such as multicolor nanopatterning and nano-inkjet devices.",

author = "Sangmin An and Corey Stambaugh and Gunn Kim and Manhee Lee and Yonghee Kim and Kunyoung Lee and Wonho Jhe",

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T1 - Low-volume liquid delivery and nanolithography using a nanopipette combined with a quartz tuning fork-atomic force microscope

AU - An, Sangmin

AU - Stambaugh, Corey

AU - Kim, Gunn

AU - Lee, Manhee

AU - Kim, Yonghee

AU - Lee, Kunyoung

AU - Jhe, Wonho

PY - 2012/10/21

Y1 - 2012/10/21

N2 - Electric-field-induced low-volume liquid ejection under ambient conditions was realized at a low bias potential of 12 V via a nanopipette (aperture diameter of 30 nm) combined with a non-contact, distance-regulated (within 10 nm) quartz tuning fork-atomic force microscope. A capillary-condensed water meniscus, spontaneously formed in the tip-substrate nanogap, reduces the ejection barrier by four orders of magnitude, facilitating nanoliquid ejection and subsequent liquid transport/dispersion onto the substrate without contact damage from the pipette. A study of nanofluidics through a free-standing liquid nanochannel and nanolithography was performed with this technique. This is an important breakthrough for various applications in controlled nanomaterial-delivery and selective deposition, such as multicolor nanopatterning and nano-inkjet devices.

AB - Electric-field-induced low-volume liquid ejection under ambient conditions was realized at a low bias potential of 12 V via a nanopipette (aperture diameter of 30 nm) combined with a non-contact, distance-regulated (within 10 nm) quartz tuning fork-atomic force microscope. A capillary-condensed water meniscus, spontaneously formed in the tip-substrate nanogap, reduces the ejection barrier by four orders of magnitude, facilitating nanoliquid ejection and subsequent liquid transport/dispersion onto the substrate without contact damage from the pipette. A study of nanofluidics through a free-standing liquid nanochannel and nanolithography was performed with this technique. This is an important breakthrough for various applications in controlled nanomaterial-delivery and selective deposition, such as multicolor nanopatterning and nano-inkjet devices.

UR - https://www.scopus.com/pages/publications/84867006356

U2 - 10.1039/c2nr30972f

DO - 10.1039/c2nr30972f

M3 - Journal article

AN - SCOPUS:84867006356

SN - 2040-3364

VL - 4

SP - 6493

EP - 6500

JO - Nanoscale

JF - Nanoscale

IS - 20

ER -

Low-volume liquid delivery and nanolithography using a nanopipette combined with a quartz tuning fork-atomic force microscope

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