Understanding how junction resistances impact the conduction mechanism in nano-networks

Cian Gabbett; Adam G. Kelly; Emmet Coleman; Luke Doolan; Tian Carey; Kevin Synnatschke; Shixin Liu; Anthony Dawson; Domhnall O’Suilleabhain; Jose Munuera; Eoin Caffrey; John B. Boland; Zdeněk Sofer; Goutam Ghosh; Sachin Kinge; Laurens D.A. Siebbeles; Neelam Yadav; Jagdish K. Vij; Muhammad Awais Aslam; Aleksandar Matkovic; Jonathan N. Coleman

doi:10.1038/s41467-024-48614-5

Understanding how junction resistances impact the conduction mechanism in nano-networks

Cian Gabbett, Adam G. Kelly, Emmet Coleman, Luke Doolan, Tian Carey, Kevin Synnatschke, Shixin Liu, Anthony Dawson, Domhnall O’Suilleabhain, Jose Munuera, Eoin Caffrey, John B. Boland, Zdeněk Sofer, Goutam Ghosh, Sachin Kinge, Laurens D.A. Siebbeles, Neelam Yadav, Jagdish K. Vij, Muhammad Awais Aslam, Aleksandar MatkovicJonathan N. Coleman

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

21 Citations (Scopus)

13 Downloads (Pure)

Abstract

Networks of nanowires, nanotubes, and nanosheets are important for many applications in printed electronics. However, the network conductivity and mobility are usually limited by the resistance between the particles, often referred to as the junction resistance. Minimising the junction resistance has proven to be challenging, partly because it is difficult to measure. Here, we develop a simple model for electrical conduction in networks of 1D or 2D nanomaterials that allows us to extract junction and nanoparticle resistances from particle-size-dependent DC network resistivity data. We find junction resistances in porous networks to scale with nanoparticle resistivity and vary from 5 Ω for silver nanosheets to 24 GΩ for WS₂ nanosheets. Moreover, our model allows junction and nanoparticle resistances to be obtained simultaneously from AC impedance spectra of semiconducting nanosheet networks. Through our model, we use the impedance data to directly link the high mobility of aligned networks of electrochemically exfoliated MoS₂ nanosheets (≈ 7 cm² V⁻¹ s⁻¹) to low junction resistances of ∼2.3 MΩ. Temperature-dependent impedance measurements also allow us to comprehensively investigate transport mechanisms within the network and quantitatively differentiate intra-nanosheet phonon-limited bandlike transport from inter-nanosheet hopping.

Original language	English
Article number	4517
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-48614-5
Publication status	Published - Dec 2024

Access to Document

10.1038/s41467-024-48614-5

s41467-024-48614-5Final published version, 3.34 MBLicence: CC BY-NC-ND

Cite this

Gabbett, C., Kelly, A. G., Coleman, E., Doolan, L., Carey, T., Synnatschke, K., Liu, S., Dawson, A., O’Suilleabhain, D., Munuera, J., Caffrey, E., Boland, J. B., Sofer, Z., Ghosh, G., Kinge, S., Siebbeles, L. D. A., Yadav, N., Vij, J. K., Aslam, M. A., ... Coleman, J. N. (2024). Understanding how junction resistances impact the conduction mechanism in nano-networks. Nature Communications, 15(1), Article 4517. https://doi.org/10.1038/s41467-024-48614-5

@article{a9d82265659543debb1e0e6b7169b6e3,

title = "Understanding how junction resistances impact the conduction mechanism in nano-networks",

abstract = "Networks of nanowires, nanotubes, and nanosheets are important for many applications in printed electronics. However, the network conductivity and mobility are usually limited by the resistance between the particles, often referred to as the junction resistance. Minimising the junction resistance has proven to be challenging, partly because it is difficult to measure. Here, we develop a simple model for electrical conduction in networks of 1D or 2D nanomaterials that allows us to extract junction and nanoparticle resistances from particle-size-dependent DC network resistivity data. We find junction resistances in porous networks to scale with nanoparticle resistivity and vary from 5 Ω for silver nanosheets to 24 GΩ for WS2 nanosheets. Moreover, our model allows junction and nanoparticle resistances to be obtained simultaneously from AC impedance spectra of semiconducting nanosheet networks. Through our model, we use the impedance data to directly link the high mobility of aligned networks of electrochemically exfoliated MoS2 nanosheets (≈ 7 cm2 V−1 s−1) to low junction resistances of ∼2.3 MΩ. Temperature-dependent impedance measurements also allow us to comprehensively investigate transport mechanisms within the network and quantitatively differentiate intra-nanosheet phonon-limited bandlike transport from inter-nanosheet hopping.",

author = "Cian Gabbett and Kelly, {Adam G.} and Emmet Coleman and Luke Doolan and Tian Carey and Kevin Synnatschke and Shixin Liu and Anthony Dawson and Domhnall O{\textquoteright}Suilleabhain and Jose Munuera and Eoin Caffrey and Boland, {John B.} and Zden{\v e}k Sofer and Goutam Ghosh and Sachin Kinge and Siebbeles, {Laurens D.A.} and Neelam Yadav and Vij, {Jagdish K.} and Aslam, {Muhammad Awais} and Aleksandar Matkovic and Coleman, {Jonathan N.}",

note = "Funding Information: We acknowledge funding from the European Union through the ERC grant FUTUREPRINT, the Graphene Flagship and the Horizon Europe project 2D-PRINTABLE (GA-101135196). We have also received support from the Science Foundation Ireland (SFI) funded centre AMBER (SFI/12/ RC/2278_P2) and availed of the facilities of the SFI-funded advanced microscopy laboratory (AML), additive research laboratory (ARL) and iCRAG. A.G.K. acknowledges funding from the Marie Sk{\l}odowska-Curie Postdoctoral Fellowship “NanoHarvest” (Proposal Number: 101107032). T.C. acknowledges funding from a Marie Sk{\l}odowska-Curie Individual Fellowship “MOVE” (grant number 101030735, project number 211395, and award number 16883). L.D appreciates support from Science Foundation Ireland (SFI) (18/EPSRC-CDT/3581). E.Ca appreciates support from the Irish Research Council (IRC) (GOIPG/2020/1051). J.M. acknowledges his Margarita Salas fellowship from the Spanish Ministry of Universities. A.M. acknowledges support from the European Research Council Starting Grant POL_2D_PHYSICS (101075821) and the Austrian Science Fund Y1298-N START Prize. NY is funded by the SFI US-Ireland project (21/US/3788). G.G., S.K. and L.D.A.S. received funding from the Netherlands Organisation for Scientific Research (NWO) in the frame- work of the Materials for sustainability and from the Ministry of Economic Affairs in the framework of the PPP allowance. Z.S. was supported by ERC-CZ program (project LL2101) from Ministry of Education Youth and Sports (MEYS) and acknowledges laser infrastructure from project reg. No. CZ.02.1.01/0.0/0.0/15_003/0000444 financed by the EFRR. We thank Prof. Matthias Moebius for useful discussions. Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = dec,

doi = "10.1038/s41467-024-48614-5",

language = "English",

volume = "15",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Nature Portfolio",

number = "1",

}

Gabbett, C, Kelly, AG, Coleman, E, Doolan, L, Carey, T, Synnatschke, K, Liu, S, Dawson, A, O’Suilleabhain, D, Munuera, J, Caffrey, E, Boland, JB, Sofer, Z, Ghosh, G, Kinge, S, Siebbeles, LDA, Yadav, N, Vij, JK, Aslam, MA, Matkovic, A & Coleman, JN 2024, 'Understanding how junction resistances impact the conduction mechanism in nano-networks', Nature Communications, vol. 15, no. 1, 4517. https://doi.org/10.1038/s41467-024-48614-5

TY - JOUR

T1 - Understanding how junction resistances impact the conduction mechanism in nano-networks

AU - Gabbett, Cian

AU - Kelly, Adam G.

AU - Coleman, Emmet

AU - Doolan, Luke

AU - Carey, Tian

AU - Synnatschke, Kevin

AU - Liu, Shixin

AU - Dawson, Anthony

AU - O’Suilleabhain, Domhnall

AU - Munuera, Jose

AU - Caffrey, Eoin

AU - Boland, John B.

AU - Sofer, Zdeněk

AU - Ghosh, Goutam

AU - Kinge, Sachin

AU - Siebbeles, Laurens D.A.

AU - Yadav, Neelam

AU - Vij, Jagdish K.

AU - Aslam, Muhammad Awais

AU - Matkovic, Aleksandar

AU - Coleman, Jonathan N.

N1 - Funding Information: We acknowledge funding from the European Union through the ERC grant FUTUREPRINT, the Graphene Flagship and the Horizon Europe project 2D-PRINTABLE (GA-101135196). We have also received support from the Science Foundation Ireland (SFI) funded centre AMBER (SFI/12/ RC/2278_P2) and availed of the facilities of the SFI-funded advanced microscopy laboratory (AML), additive research laboratory (ARL) and iCRAG. A.G.K. acknowledges funding from the Marie Skłodowska-Curie Postdoctoral Fellowship “NanoHarvest” (Proposal Number: 101107032). T.C. acknowledges funding from a Marie Skłodowska-Curie Individual Fellowship “MOVE” (grant number 101030735, project number 211395, and award number 16883). L.D appreciates support from Science Foundation Ireland (SFI) (18/EPSRC-CDT/3581). E.Ca appreciates support from the Irish Research Council (IRC) (GOIPG/2020/1051). J.M. acknowledges his Margarita Salas fellowship from the Spanish Ministry of Universities. A.M. acknowledges support from the European Research Council Starting Grant POL_2D_PHYSICS (101075821) and the Austrian Science Fund Y1298-N START Prize. NY is funded by the SFI US-Ireland project (21/US/3788). G.G., S.K. and L.D.A.S. received funding from the Netherlands Organisation for Scientific Research (NWO) in the frame- work of the Materials for sustainability and from the Ministry of Economic Affairs in the framework of the PPP allowance. Z.S. was supported by ERC-CZ program (project LL2101) from Ministry of Education Youth and Sports (MEYS) and acknowledges laser infrastructure from project reg. No. CZ.02.1.01/0.0/0.0/15_003/0000444 financed by the EFRR. We thank Prof. Matthias Moebius for useful discussions. Publisher Copyright: © The Author(s) 2024.

PY - 2024/12

Y1 - 2024/12

N2 - Networks of nanowires, nanotubes, and nanosheets are important for many applications in printed electronics. However, the network conductivity and mobility are usually limited by the resistance between the particles, often referred to as the junction resistance. Minimising the junction resistance has proven to be challenging, partly because it is difficult to measure. Here, we develop a simple model for electrical conduction in networks of 1D or 2D nanomaterials that allows us to extract junction and nanoparticle resistances from particle-size-dependent DC network resistivity data. We find junction resistances in porous networks to scale with nanoparticle resistivity and vary from 5 Ω for silver nanosheets to 24 GΩ for WS2 nanosheets. Moreover, our model allows junction and nanoparticle resistances to be obtained simultaneously from AC impedance spectra of semiconducting nanosheet networks. Through our model, we use the impedance data to directly link the high mobility of aligned networks of electrochemically exfoliated MoS2 nanosheets (≈ 7 cm2 V−1 s−1) to low junction resistances of ∼2.3 MΩ. Temperature-dependent impedance measurements also allow us to comprehensively investigate transport mechanisms within the network and quantitatively differentiate intra-nanosheet phonon-limited bandlike transport from inter-nanosheet hopping.

AB - Networks of nanowires, nanotubes, and nanosheets are important for many applications in printed electronics. However, the network conductivity and mobility are usually limited by the resistance between the particles, often referred to as the junction resistance. Minimising the junction resistance has proven to be challenging, partly because it is difficult to measure. Here, we develop a simple model for electrical conduction in networks of 1D or 2D nanomaterials that allows us to extract junction and nanoparticle resistances from particle-size-dependent DC network resistivity data. We find junction resistances in porous networks to scale with nanoparticle resistivity and vary from 5 Ω for silver nanosheets to 24 GΩ for WS2 nanosheets. Moreover, our model allows junction and nanoparticle resistances to be obtained simultaneously from AC impedance spectra of semiconducting nanosheet networks. Through our model, we use the impedance data to directly link the high mobility of aligned networks of electrochemically exfoliated MoS2 nanosheets (≈ 7 cm2 V−1 s−1) to low junction resistances of ∼2.3 MΩ. Temperature-dependent impedance measurements also allow us to comprehensively investigate transport mechanisms within the network and quantitatively differentiate intra-nanosheet phonon-limited bandlike transport from inter-nanosheet hopping.

UR - http://www.scopus.com/inward/record.url?scp=85194864868&partnerID=8YFLogxK

U2 - 10.1038/s41467-024-48614-5

DO - 10.1038/s41467-024-48614-5

M3 - Article

C2 - 38806479

AN - SCOPUS:85194864868

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 4517

ER -

Understanding how junction resistances impact the conduction mechanism in nano-networks

Abstract

Access to Document

Other files and links

Cite this