Towards Oxide Electronics: a Roadmap

M. Coll, J. Fontcuberta, M. Althammer, M. Bibes, H. Boschker, A. Calleja, G. Cheng, M. Cuoco, R. Dittmann, B. Dkhil, I. El Baggari, M. Fanciulli, I. Fina, E. Fortunato, C. Frontera, S. Fujita, V. Garcia, S. T.B. Goennenwein, C. G. Granqvist, J. Grollier & 36 others R. Gross, A. Hagfeldt, G. Herranz, K. Hono, E. Houwman, M. Huijben, A. Kalaboukhov, D. J. Keeble, G. Koster, L. F. Kourkoutis, J. Levy, M. Lira-Cantu, J. L. MacManus-Driscoll, Jochen Mannhart, R. Martins, S. Menzel, T. Mikolajick, M. Napari, M. D. Nguyen, G. Niklasson, C. Paillard, S. Panigrahi, G. Rijnders, F. Sánchez, P. Sanchis, S. Sanna, D. G. Schlom, U. Schroeder, K. M. Shen, A. Siemon, M. Spreitzer, H. Sukegawa, R. Tamayo, J. van den Brink, N. Pryds, F. Miletto Granozio*

*Corresponding author for this work

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Abstract

At the end of a rush lasting over half a century, in which CMOS technology has been experiencing a constant and breathtaking increase of device speed and density, Moore’s law is approaching the insurmountable barrier given by the ultimate atomic nature of matter. A major challenge for 21st century scientists is finding novel strategies, concepts and materials for replacing silicon-based CMOS semiconductor technologies and guaranteeing a continued and steady technological progress in next decades. Among the materials classes candidate to contribute to this momentous challenge, oxide films and heterostructures are a particularly appealing hunting ground. The vastity, intended in pure chemical terms, of this class of compounds, the complexity of their correlated behaviour, and the wealth of functional properties they display, has already made these systems the subject of choice, worldwide, of a strongly networked, dynamic and interdisciplinary research community.

Oxide science and technology has been the target of a wide four-year project, named Towards Oxide-Based Electronics (TO-BE), that has been recently running in Europe and has involved as participants several hundred scientists from 29 EU countries. In this review and perspective paper, published as a final deliverable of the TO-BE Action, the opportunities of oxides as future electronic materials for Information and Communication Technologies ICT and Energy are discussed. The paper is organized as a set of contributions, all selected and ordered as individual building blocks of a wider general scheme. After a brief preface by the editors and an introductory contribution, two sections follow. The first is mainly devoted to providing a perspective on the latest theoretical and experimental methods that are employed to investigate oxides and to produce oxide-based films, heterostructures and devices. In the second, all contributions are dedicated to different specific fields of applications of oxide thin films and heterostructures, in sectors as data storage and computing, optics and plasmonics, magnonics, energy conversion and harvesting, and power electronics.
Original languageEnglish
JournalApplied Surface Science
Volume482
Pages (from-to)1-93
Number of pages93
ISSN0169-4332
DOIs
Publication statusPublished - 2019

Keywords

  • Oxides
  • Oxide electronics
  • Periodic table

Cite this

Coll, M., Fontcuberta, J., Althammer, M., Bibes, M., Boschker, H., Calleja, A., ... Granozio, F. M. (2019). Towards Oxide Electronics: a Roadmap. Applied Surface Science, 482, 1-93. https://doi.org/10.1016/j.apsusc.2019.03.312
Coll, M. ; Fontcuberta, J. ; Althammer, M. ; Bibes, M. ; Boschker, H. ; Calleja, A. ; Cheng, G. ; Cuoco, M. ; Dittmann, R. ; Dkhil, B. ; El Baggari, I. ; Fanciulli, M. ; Fina, I. ; Fortunato, E. ; Frontera, C. ; Fujita, S. ; Garcia, V. ; Goennenwein, S. T.B. ; Granqvist, C. G. ; Grollier, J. ; Gross, R. ; Hagfeldt, A. ; Herranz, G. ; Hono, K. ; Houwman, E. ; Huijben, M. ; Kalaboukhov, A. ; Keeble, D. J. ; Koster, G. ; Kourkoutis, L. F. ; Levy, J. ; Lira-Cantu, M. ; MacManus-Driscoll, J. L. ; Mannhart, Jochen ; Martins, R. ; Menzel, S. ; Mikolajick, T. ; Napari, M. ; Nguyen, M. D. ; Niklasson, G. ; Paillard, C. ; Panigrahi, S. ; Rijnders, G. ; Sánchez, F. ; Sanchis, P. ; Sanna, S. ; Schlom, D. G. ; Schroeder, U. ; Shen, K. M. ; Siemon, A. ; Spreitzer, M. ; Sukegawa, H. ; Tamayo, R. ; van den Brink, J. ; Pryds, N. ; Granozio, F. Miletto. / Towards Oxide Electronics: a Roadmap. In: Applied Surface Science. 2019 ; Vol. 482. pp. 1-93.
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abstract = "At the end of a rush lasting over half a century, in which CMOS technology has been experiencing a constant and breathtaking increase of device speed and density, Moore’s law is approaching the insurmountable barrier given by the ultimate atomic nature of matter. A major challenge for 21st century scientists is finding novel strategies, concepts and materials for replacing silicon-based CMOS semiconductor technologies and guaranteeing a continued and steady technological progress in next decades. Among the materials classes candidate to contribute to this momentous challenge, oxide films and heterostructures are a particularly appealing hunting ground. The vastity, intended in pure chemical terms, of this class of compounds, the complexity of their correlated behaviour, and the wealth of functional properties they display, has already made these systems the subject of choice, worldwide, of a strongly networked, dynamic and interdisciplinary research community.Oxide science and technology has been the target of a wide four-year project, named Towards Oxide-Based Electronics (TO-BE), that has been recently running in Europe and has involved as participants several hundred scientists from 29 EU countries. In this review and perspective paper, published as a final deliverable of the TO-BE Action, the opportunities of oxides as future electronic materials for Information and Communication Technologies ICT and Energy are discussed. The paper is organized as a set of contributions, all selected and ordered as individual building blocks of a wider general scheme. After a brief preface by the editors and an introductory contribution, two sections follow. The first is mainly devoted to providing a perspective on the latest theoretical and experimental methods that are employed to investigate oxides and to produce oxide-based films, heterostructures and devices. In the second, all contributions are dedicated to different specific fields of applications of oxide thin films and heterostructures, in sectors as data storage and computing, optics and plasmonics, magnonics, energy conversion and harvesting, and power electronics.",
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doi = "10.1016/j.apsusc.2019.03.312",
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Coll, M, Fontcuberta, J, Althammer, M, Bibes, M, Boschker, H, Calleja, A, Cheng, G, Cuoco, M, Dittmann, R, Dkhil, B, El Baggari, I, Fanciulli, M, Fina, I, Fortunato, E, Frontera, C, Fujita, S, Garcia, V, Goennenwein, STB, Granqvist, CG, Grollier, J, Gross, R, Hagfeldt, A, Herranz, G, Hono, K, Houwman, E, Huijben, M, Kalaboukhov, A, Keeble, DJ, Koster, G, Kourkoutis, LF, Levy, J, Lira-Cantu, M, MacManus-Driscoll, JL, Mannhart, J, Martins, R, Menzel, S, Mikolajick, T, Napari, M, Nguyen, MD, Niklasson, G, Paillard, C, Panigrahi, S, Rijnders, G, Sánchez, F, Sanchis, P, Sanna, S, Schlom, DG, Schroeder, U, Shen, KM, Siemon, A, Spreitzer, M, Sukegawa, H, Tamayo, R, van den Brink, J, Pryds, N & Granozio, FM 2019, 'Towards Oxide Electronics: a Roadmap', Applied Surface Science, vol. 482, pp. 1-93. https://doi.org/10.1016/j.apsusc.2019.03.312

Towards Oxide Electronics: a Roadmap. / Coll, M.; Fontcuberta, J.; Althammer, M.; Bibes, M.; Boschker, H.; Calleja, A.; Cheng, G.; Cuoco, M.; Dittmann, R.; Dkhil, B.; El Baggari, I.; Fanciulli, M.; Fina, I.; Fortunato, E.; Frontera, C.; Fujita, S.; Garcia, V.; Goennenwein, S. T.B.; Granqvist, C. G.; Grollier, J.; Gross, R.; Hagfeldt, A.; Herranz, G.; Hono, K.; Houwman, E.; Huijben, M.; Kalaboukhov, A.; Keeble, D. J.; Koster, G.; Kourkoutis, L. F.; Levy, J.; Lira-Cantu, M.; MacManus-Driscoll, J. L.; Mannhart, Jochen; Martins, R.; Menzel, S.; Mikolajick, T.; Napari, M.; Nguyen, M. D.; Niklasson, G.; Paillard, C.; Panigrahi, S.; Rijnders, G.; Sánchez, F.; Sanchis, P.; Sanna, S.; Schlom, D. G.; Schroeder, U.; Shen, K. M.; Siemon, A.; Spreitzer, M.; Sukegawa, H.; Tamayo, R.; van den Brink, J.; Pryds, N.; Granozio, F. Miletto.

In: Applied Surface Science, Vol. 482, 2019, p. 1-93.

Research output: Contribution to journalJournal articleResearchpeer-review

TY - JOUR

T1 - Towards Oxide Electronics: a Roadmap

AU - Coll, M.

AU - Fontcuberta, J.

AU - Althammer, M.

AU - Bibes, M.

AU - Boschker, H.

AU - Calleja, A.

AU - Cheng, G.

AU - Cuoco, M.

AU - Dittmann, R.

AU - Dkhil, B.

AU - El Baggari, I.

AU - Fanciulli, M.

AU - Fina, I.

AU - Fortunato, E.

AU - Frontera, C.

AU - Fujita, S.

AU - Garcia, V.

AU - Goennenwein, S. T.B.

AU - Granqvist, C. G.

AU - Grollier, J.

AU - Gross, R.

AU - Hagfeldt, A.

AU - Herranz, G.

AU - Hono, K.

AU - Houwman, E.

AU - Huijben, M.

AU - Kalaboukhov, A.

AU - Keeble, D. J.

AU - Koster, G.

AU - Kourkoutis, L. F.

AU - Levy, J.

AU - Lira-Cantu, M.

AU - MacManus-Driscoll, J. L.

AU - Mannhart, Jochen

AU - Martins, R.

AU - Menzel, S.

AU - Mikolajick, T.

AU - Napari, M.

AU - Nguyen, M. D.

AU - Niklasson, G.

AU - Paillard, C.

AU - Panigrahi, S.

AU - Rijnders, G.

AU - Sánchez, F.

AU - Sanchis, P.

AU - Sanna, S.

AU - Schlom, D. G.

AU - Schroeder, U.

AU - Shen, K. M.

AU - Siemon, A.

AU - Spreitzer, M.

AU - Sukegawa, H.

AU - Tamayo, R.

AU - van den Brink, J.

AU - Pryds, N.

AU - Granozio, F. Miletto

PY - 2019

Y1 - 2019

N2 - At the end of a rush lasting over half a century, in which CMOS technology has been experiencing a constant and breathtaking increase of device speed and density, Moore’s law is approaching the insurmountable barrier given by the ultimate atomic nature of matter. A major challenge for 21st century scientists is finding novel strategies, concepts and materials for replacing silicon-based CMOS semiconductor technologies and guaranteeing a continued and steady technological progress in next decades. Among the materials classes candidate to contribute to this momentous challenge, oxide films and heterostructures are a particularly appealing hunting ground. The vastity, intended in pure chemical terms, of this class of compounds, the complexity of their correlated behaviour, and the wealth of functional properties they display, has already made these systems the subject of choice, worldwide, of a strongly networked, dynamic and interdisciplinary research community.Oxide science and technology has been the target of a wide four-year project, named Towards Oxide-Based Electronics (TO-BE), that has been recently running in Europe and has involved as participants several hundred scientists from 29 EU countries. In this review and perspective paper, published as a final deliverable of the TO-BE Action, the opportunities of oxides as future electronic materials for Information and Communication Technologies ICT and Energy are discussed. The paper is organized as a set of contributions, all selected and ordered as individual building blocks of a wider general scheme. After a brief preface by the editors and an introductory contribution, two sections follow. The first is mainly devoted to providing a perspective on the latest theoretical and experimental methods that are employed to investigate oxides and to produce oxide-based films, heterostructures and devices. In the second, all contributions are dedicated to different specific fields of applications of oxide thin films and heterostructures, in sectors as data storage and computing, optics and plasmonics, magnonics, energy conversion and harvesting, and power electronics.

AB - At the end of a rush lasting over half a century, in which CMOS technology has been experiencing a constant and breathtaking increase of device speed and density, Moore’s law is approaching the insurmountable barrier given by the ultimate atomic nature of matter. A major challenge for 21st century scientists is finding novel strategies, concepts and materials for replacing silicon-based CMOS semiconductor technologies and guaranteeing a continued and steady technological progress in next decades. Among the materials classes candidate to contribute to this momentous challenge, oxide films and heterostructures are a particularly appealing hunting ground. The vastity, intended in pure chemical terms, of this class of compounds, the complexity of their correlated behaviour, and the wealth of functional properties they display, has already made these systems the subject of choice, worldwide, of a strongly networked, dynamic and interdisciplinary research community.Oxide science and technology has been the target of a wide four-year project, named Towards Oxide-Based Electronics (TO-BE), that has been recently running in Europe and has involved as participants several hundred scientists from 29 EU countries. In this review and perspective paper, published as a final deliverable of the TO-BE Action, the opportunities of oxides as future electronic materials for Information and Communication Technologies ICT and Energy are discussed. The paper is organized as a set of contributions, all selected and ordered as individual building blocks of a wider general scheme. After a brief preface by the editors and an introductory contribution, two sections follow. The first is mainly devoted to providing a perspective on the latest theoretical and experimental methods that are employed to investigate oxides and to produce oxide-based films, heterostructures and devices. In the second, all contributions are dedicated to different specific fields of applications of oxide thin films and heterostructures, in sectors as data storage and computing, optics and plasmonics, magnonics, energy conversion and harvesting, and power electronics.

KW - Oxides

KW - Oxide electronics

KW - Periodic table

U2 - 10.1016/j.apsusc.2019.03.312

DO - 10.1016/j.apsusc.2019.03.312

M3 - Journal article

VL - 482

SP - 1

EP - 93

JO - Applied Surface Science

JF - Applied Surface Science

SN - 0169-4332

ER -

Coll M, Fontcuberta J, Althammer M, Bibes M, Boschker H, Calleja A et al. Towards Oxide Electronics: a Roadmap. Applied Surface Science. 2019;482:1-93. https://doi.org/10.1016/j.apsusc.2019.03.312