High-resolution additive manufacturing for 3D multifunctional microelectronic devices

Jeroen A.H.P. Sol; Marwan Aarab; Wilko van Grondelle; Darragh R. Walsh; Sophie C.E. Suijdendorp; Joris J.C. Remmers; Hylke B. Akkerman

doi:10.1117/12.3040844

High-resolution additive manufacturing for 3D multifunctional microelectronic devices

Jeroen A.H.P. Sol, Marwan Aarab, Wilko van Grondelle, Darragh R. Walsh, Sophie C.E. Suijdendorp, Joris J.C. Remmers, Hylke B. Akkerman

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/Congresprocedure › Conferentiebijdrage › Academic

Samenvatting

To meet future demands for microelectronic devices—dimensional, environmental, functional—new fabrication technologies are sought after. Manufacturing technologies that minimize the footprint of such devices while concurrently integrating electronics with other functionalities such as microfluidics. This is made possible by 3D printing electronics at high resolution and incorporating and interconnecting bare die chips. At Holst Centre, we have been developing a multimaterial additive manufacturing technology to meet these demands. “3D Additive Lithography for Electronics” combines high-resolution direct imaging lithography with groove filling with conductive metal pastes to build structural electronics with down to 10 µm feature sizes. The structural material, a photopolymerizable resin, is patterned using a DMD-based light engine that scans over the build area. A custom-built foil recoating solution provides fresh resin to the build area as the printing progresses, and industry-standard metal pastes are used to interconnect incorporated functional components in the 100 µm to several mm size range.

Originele taal-2	Engels
Titel	Emerging Digital Micromirror Device Based Systems and Applications XVII
Redacteuren	Benjamin L. Lee, Alex Lyubarsky
Uitgeverij	SPIE
Aantal pagina's	8
ISBN van elektronische versie	9781510685154
ISBN van geprinte versie	9781510685147
DOI's	https://doi.org/10.1117/12.3040844
Status	Gepubliceerd - 19 mrt. 2025
Evenement	OPTO - San Francisco, Verenigde Staten van Amerika Duur: 25 jan. 2025 → 31 jan. 2025

Publicatie series

Naam	Proceedings of SPIE
Volume	13383
ISSN van geprinte versie	0277-786X
ISSN van elektronische versie	1996-756X

Congres

Congres	OPTO
Land/Regio	Verenigde Staten van Amerika
Stad	San Francisco
Periode	25/01/25 → 31/01/25

Financiering

The authors would like to express their gratitude to Roel H.L. Kusters, Pim Ostendorf, Bart Peeters, Lianne Tuin, Fabien B. J. Bruning, Rob J. Hendriks, Dr. Jacqueline van Driel, Dr. Jeroen van den Brand (all TNO at Holst Centre), Emma C. Munnig Schmidt (TNO), and Dr. Marc G.D. Geers (TU/e) for their experimental help and theoretical and practical insights. This research is in part made possible by a contribution from the National Growth Fund program NXTGEN Hightech.

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Emerging DMD Based Systems and Applications Best Paper Award
Sol, J. A. H. P. (Ontvanger), Aarab, M. (Ontvanger), van Grondelle, W. (Ontvanger), Walsh, D. R. (Ontvanger), Suijdendorp, S. C. E. (Ontvanger), Remmers, J. J. C. (Ontvanger) & Akkerman, H. B. (Ontvanger), 2025
Prijs: Anders › Werk, activiteit of publicatie gerelateerde prijzen (lifetime, best paper, poster etc.) › Wetenschappelijk

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Sol, J. A. H. P., Aarab, M., van Grondelle, W., Walsh, D. R., Suijdendorp, S. C. E., Remmers, J. J. C., & Akkerman, H. B. (2025). High-resolution additive manufacturing for 3D multifunctional microelectronic devices. In B. L. Lee, & A. Lyubarsky (editors), Emerging Digital Micromirror Device Based Systems and Applications XVII Artikel 1338302 (Proceedings of SPIE; Vol. 13383). SPIE. https://doi.org/10.1117/12.3040844

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abstract = "To meet future demands for microelectronic devices—dimensional, environmental, functional—new fabrication technologies are sought after. Manufacturing technologies that minimize the footprint of such devices while concurrently integrating electronics with other functionalities such as microfluidics. This is made possible by 3D printing electronics at high resolution and incorporating and interconnecting bare die chips. At Holst Centre, we have been developing a multimaterial additive manufacturing technology to meet these demands. “3D Additive Lithography for Electronics” combines high-resolution direct imaging lithography with groove filling with conductive metal pastes to build structural electronics with down to 10 µm feature sizes. The structural material, a photopolymerizable resin, is patterned using a DMD-based light engine that scans over the build area. A custom-built foil recoating solution provides fresh resin to the build area as the printing progresses, and industry-standard metal pastes are used to interconnect incorporated functional components in the 100 µm to several mm size range.",

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Sol, JAHP, Aarab, M, van Grondelle, W, Walsh, DR, Suijdendorp, SCE, Remmers, JJC & Akkerman, HB 2025, High-resolution additive manufacturing for 3D multifunctional microelectronic devices. in BL Lee & A Lyubarsky (uitgave), Emerging Digital Micromirror Device Based Systems and Applications XVII., 1338302, Proceedings of SPIE, vol. 13383, SPIE, OPTO, San Francisco, Verenigde Staten van Amerika, 25/01/25. https://doi.org/10.1117/12.3040844

High-resolution additive manufacturing for 3D multifunctional microelectronic devices. / Sol, Jeroen A.H.P.; Aarab, Marwan; van Grondelle, Wilko et al.
Emerging Digital Micromirror Device Based Systems and Applications XVII. uitgave / Benjamin L. Lee; Alex Lyubarsky. SPIE, 2025. 1338302 (Proceedings of SPIE; Vol. 13383).

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/Congresprocedure › Conferentiebijdrage › Academic

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High-resolution additive manufacturing for 3D multifunctional microelectronic devices

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Financiering

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Emerging DMD Based Systems and Applications Best Paper Award

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