Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag2O membranes within etched tracks and of their precursor structures

Dietmar Fink; W. R. Fahrner; K. Hoppe; G. Muñoz Hernandez; H. García Arellano; A. Kiv; J. Vacik; L. Alfonta

doi:10.1201/b16746

Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag₂O membranes within etched tracks and of their precursor structures

Dietmar Fink, W. R. Fahrner, K. Hoppe, G. Muñoz Hernandez, H. García Arellano, A. Kiv, J. Vacik, L. Alfonta

Department of Life Sciences

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Since about half a century, it is known that the transition of swift heavy ions through thin polymer foils leaves a trail of radiochemical and structural damage behind-the so-called latent tracks-that can easily be removed by adequate etchants, thus creating nanopores, the so-called etched tracks [1]. With a previously developed strategy, it is also possible to create nanopores with central membranes embedded therein, thus separating the pores into two independent individual adjacent compartments (part I of this series [2]). The membranes can consist of, for example, Ag₂O [2] or other materials such as LiF, CaO, or BaCO₃ (to be published). In the same way as normal etched tracks can be filled with various materials of interest for electronics [3-9], medicine [10], or biosensing [11-19], also these nanopores with central membranes can be used for various applications. That will be treated in the next paper of this series.

Original language	English
Title of host publication	Technologies for Smart Sensors and Sensor Fusion
Publisher	CRC Press
Pages	161-175
Number of pages	15
ISBN (Electronic)	9781466595514
ISBN (Print)	9781466595507
DOIs	https://doi.org/10.1201/b16746
State	Published - 1 Jan 2017

ASJC Scopus subject areas

General Engineering
General Physics and Astronomy

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10.1201/b16746

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Fink, D., Fahrner, W. R., Hoppe, K., Hernandez, G. M., Arellano, H. G., Kiv, A., Vacik, J., & Alfonta, L. (2017). Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag₂O membranes within etched tracks and of their precursor structures. In Technologies for Smart Sensors and Sensor Fusion (pp. 161-175). CRC Press. https://doi.org/10.1201/b16746

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title = "Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag2O membranes within etched tracks and of their precursor structures",

abstract = "Since about half a century, it is known that the transition of swift heavy ions through thin polymer foils leaves a trail of radiochemical and structural damage behind-the so-called latent tracks-that can easily be removed by adequate etchants, thus creating nanopores, the so-called etched tracks [1]. With a previously developed strategy, it is also possible to create nanopores with central membranes embedded therein, thus separating the pores into two independent individual adjacent compartments (part I of this series [2]). The membranes can consist of, for example, Ag2O [2] or other materials such as LiF, CaO, or BaCO3 (to be published). In the same way as normal etched tracks can be filled with various materials of interest for electronics [3-9], medicine [10], or biosensing [11-19], also these nanopores with central membranes can be used for various applications. That will be treated in the next paper of this series.",

author = "Dietmar Fink and Fahrner, \{W. R.\} and K. Hoppe and Hernandez, \{G. Mu{\~n}oz\} and Arellano, \{H. Garc{\'i}a\} and A. Kiv and J. Vacik and L. Alfonta",

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doi = "10.1201/b16746",

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Fink, D, Fahrner, WR, Hoppe, K, Hernandez, GM, Arellano, HG, Kiv, A, Vacik, J & Alfonta, L 2017, Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag₂O membranes within etched tracks and of their precursor structures. in Technologies for Smart Sensors and Sensor Fusion. CRC Press, pp. 161-175. https://doi.org/10.1201/b16746

Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag₂O membranes within etched tracks and of their precursor structures. / Fink, Dietmar; Fahrner, W. R.; Hoppe, K. et al.
Technologies for Smart Sensors and Sensor Fusion. CRC Press, 2017. p. 161-175.

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

TY - CHAP

T1 - Coupled chemical reactions in dynamic nanometric confinement

T2 - III. Electronic characterization of Ag2O membranes within etched tracks and of their precursor structures

AU - Fink, Dietmar

AU - Fahrner, W. R.

AU - Hoppe, K.

AU - Hernandez, G. Muñoz

AU - Arellano, H. García

AU - Kiv, A.

AU - Vacik, J.

AU - Alfonta, L.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - Since about half a century, it is known that the transition of swift heavy ions through thin polymer foils leaves a trail of radiochemical and structural damage behind-the so-called latent tracks-that can easily be removed by adequate etchants, thus creating nanopores, the so-called etched tracks [1]. With a previously developed strategy, it is also possible to create nanopores with central membranes embedded therein, thus separating the pores into two independent individual adjacent compartments (part I of this series [2]). The membranes can consist of, for example, Ag2O [2] or other materials such as LiF, CaO, or BaCO3 (to be published). In the same way as normal etched tracks can be filled with various materials of interest for electronics [3-9], medicine [10], or biosensing [11-19], also these nanopores with central membranes can be used for various applications. That will be treated in the next paper of this series.

AB - Since about half a century, it is known that the transition of swift heavy ions through thin polymer foils leaves a trail of radiochemical and structural damage behind-the so-called latent tracks-that can easily be removed by adequate etchants, thus creating nanopores, the so-called etched tracks [1]. With a previously developed strategy, it is also possible to create nanopores with central membranes embedded therein, thus separating the pores into two independent individual adjacent compartments (part I of this series [2]). The membranes can consist of, for example, Ag2O [2] or other materials such as LiF, CaO, or BaCO3 (to be published). In the same way as normal etched tracks can be filled with various materials of interest for electronics [3-9], medicine [10], or biosensing [11-19], also these nanopores with central membranes can be used for various applications. That will be treated in the next paper of this series.

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SN - 9781466595507

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BT - Technologies for Smart Sensors and Sensor Fusion

PB - CRC Press

ER -

Coupled chemical reactions in dynamic nanometric confinement: III. Electronic characterization of Ag₂O membranes within etched tracks and of their precursor structures

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