A carbene stabilized precursor for the spatial atomic layer deposition of copper thin films

Nils Boysen; Bujamin Misimi; Arbresha Muriqi; Jan Lucas Wree; Tim Hasselmann; Detlef Rogalla; Tobias Haeger; Detlef Theirich; Michael Nolan; Thomas Riedl; Anjana Devi

doi:10.1039/d0cc05781a

A carbene stabilized precursor for the spatial atomic layer deposition of copper thin films

Nils Boysen
, Bujamin Misimi
, Arbresha Muriqi
, Jan Lucas Wree
, Tim Hasselmann
, Detlef Rogalla
, Tobias Haeger
, Detlef Theirich
, Michael Nolan
, Thomas Riedl
, Anjana Devi

Research output: Contribution to journal › Article › peer-review

Abstract

This paper demonstrates a carbene stabilized precursor [Cu(tBuNHC)(hmds)] with suitable volatility, reactivity and thermal stability, that enables the spatial plasma-enhanced atomic layer deposition (APP-ALD) of copper thin films at atmospheric pressure. The resulting conductive and pure copper layers were thoroughly analysed and a comparison of precursor and process with the previously reported silver analogue [Ag(tBuNHC)(hmds)] revealed interesting similarities and notable differences in precursor chemistry and growth characteristics. This first report of APP-ALD grown copper layers is an important starting point for high throughput, low-cost manufacturing of copper films for nano- and optoelectronic devices.

Original language	English
Pages (from-to)	13752-13755
Number of pages	4
Journal	Chemical Communications
Volume	56
Issue number	89
DOIs	https://doi.org/10.1039/d0cc05781a
Publication status	Published - 18 Nov 2020

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10.1039/d0cc05781a

https://hdl.handle.net/10468/10759Licence: CC BY-NC-ND

Cite this

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title = "A carbene stabilized precursor for the spatial atomic layer deposition of copper thin films",

abstract = "This paper demonstrates a carbene stabilized precursor [Cu(tBuNHC)(hmds)] with suitable volatility, reactivity and thermal stability, that enables the spatial plasma-enhanced atomic layer deposition (APP-ALD) of copper thin films at atmospheric pressure. The resulting conductive and pure copper layers were thoroughly analysed and a comparison of precursor and process with the previously reported silver analogue [Ag(tBuNHC)(hmds)] revealed interesting similarities and notable differences in precursor chemistry and growth characteristics. This first report of APP-ALD grown copper layers is an important starting point for high throughput, low-cost manufacturing of copper films for nano- and optoelectronic devices.",

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doi = "10.1039/d0cc05781a",

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AU - Boysen, Nils

AU - Misimi, Bujamin

AU - Muriqi, Arbresha

AU - Wree, Jan Lucas

AU - Hasselmann, Tim

AU - Rogalla, Detlef

AU - Haeger, Tobias

AU - Theirich, Detlef

AU - Nolan, Michael

AU - Riedl, Thomas

AU - Devi, Anjana

PY - 2020/11/18

Y1 - 2020/11/18

N2 - This paper demonstrates a carbene stabilized precursor [Cu(tBuNHC)(hmds)] with suitable volatility, reactivity and thermal stability, that enables the spatial plasma-enhanced atomic layer deposition (APP-ALD) of copper thin films at atmospheric pressure. The resulting conductive and pure copper layers were thoroughly analysed and a comparison of precursor and process with the previously reported silver analogue [Ag(tBuNHC)(hmds)] revealed interesting similarities and notable differences in precursor chemistry and growth characteristics. This first report of APP-ALD grown copper layers is an important starting point for high throughput, low-cost manufacturing of copper films for nano- and optoelectronic devices.

AB - This paper demonstrates a carbene stabilized precursor [Cu(tBuNHC)(hmds)] with suitable volatility, reactivity and thermal stability, that enables the spatial plasma-enhanced atomic layer deposition (APP-ALD) of copper thin films at atmospheric pressure. The resulting conductive and pure copper layers were thoroughly analysed and a comparison of precursor and process with the previously reported silver analogue [Ag(tBuNHC)(hmds)] revealed interesting similarities and notable differences in precursor chemistry and growth characteristics. This first report of APP-ALD grown copper layers is an important starting point for high throughput, low-cost manufacturing of copper films for nano- and optoelectronic devices.

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VL - 56

SP - 13752

EP - 13755

JO - Chemical Communications

JF - Chemical Communications

IS - 89

ER -

A carbene stabilized precursor for the spatial atomic layer deposition of copper thin films

Abstract

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