2026 Dago M. de Leeuw: Materials Science Researcher – H-Index, Publications & Awards

Discipline name	D-Index	World Ranking	Current World Ranking	National Ranking	Current National Ranking	Publications	Citations
Materials Science	100	1037	990	14	12	346	47855

Discipline name

D-Index

World Ranking

Current World Ranking

National Ranking

Current National Ranking

Publications

Citations

Materials Science

100

1037

990

346

47855

Research.com Recognitions

2022 - Research.com Materials Science in Netherlands Leader Award

Overview

Dago M. de Leeuw is a researcher affiliated with the Holst Centre in the Netherlands. Their work primarily focuses on engineering, with a notable emphasis on biomedical engineering and electrical and electronic engineering. This cross-disciplinary approach extends to subfields including cardiology and cardiovascular medicine, as well as polymers and plastics.

Their research encompasses several topics related to advanced materials and biomedical applications. These include:

Non-Invasive Vital Sign Monitoring
Advanced Sensor and Energy Harvesting Materials
ECG Monitoring and Analysis
Organic Electronics and Photovoltaics
Conducting Polymers and Applications
Organic Light-Emitting Diodes Research

Dago M. de Leeuw has contributed scholarly articles to prominent scientific venues. Their publications have appeared in:

Advanced Materials Technologies
Physical Review B

Two recent papers illustrate the scope of their investigations. The first, published in 2024 in Advanced Materials Technologies, is titled "Large Area Ballistocardiography Enabled by Printed Piezoelectric Sensor Arrays on Elastomeric Substrates." This work explores novel sensor arrays suitable for physiological monitoring.

The second paper, from 2020 in Physical Review B, is "Reply to 'Comment on "Charge transport in disordered semiconducting polymers driven by nuclear tunneling"'." This publication engages with charge transport phenomena in polymers, reflecting their interest in organic electronic materials.

Collaboration forms a significant aspect of their research. Frequent co-authors include:

Peter Zalar
Marieke Burghoorn
Joost A. Fijn
Lars Rikken
Peter A. Rensing

This body of work collectively situates Dago M. de Leeuw at the intersection of materials science, sensor development, and biomedical applications, focusing on promising technologies that bridge organic electronics with health monitoring systems.

Best Publications

Two-dimensional charge transport in self-organized, high-mobility conjugated polymers

Henning Sirringhaus;P. J. Brown;R. H. Friend;M. M. Nielsen

5628
Citations
Flexible active-matrix displays and shift registers based on solution-processed organic transistors.

Gerwin H. Gelinck;H. Edzer A. Huitema;Erik van Veenendaal;Eugenio Cantatore

1970
Citations
Stability of n-type doped conducting polymers and consequences for polymeric microelectronic devices

D.M. de Leeuw;M.M.J. Simenon;A.R. Brown;R.E.F. Einerhand

1787
Citations
Unified Description of Charge-Carrier Mobilities in Disordered Semiconducting Polymers

W.F. Pasveer;J. Cottaar;C. Tanase;R. Coehoorn

1191
Citations
Gate Insulators in Organic Field-Effect Transistors

Janos Veres;and Simon Ogier;Giles Lloyd;Dago de Leeuw

1172
Citations
Low-cost all-polymer integrated circuits

C. J. Drury;C. M. J. Mutsaers;C. M. Hart;M. Matters

1141
Citations
Solution-processed ambipolar organic field-effect transistors and inverters.

E.J. Meijer;E.J. Meijer;D.M. de Leeuw;S. Setayesh;E. van Veenendaal

1096
Citations
High-performance solution-processed polymer ferroelectric field-effect transistors

Ronald C. G. Naber;Cristina Tanase;Paul W. M. Blom;Gerwin H. Gelinck

1061
Citations
Unification of the hole transport in polymeric field-effect transistors and light-emitting diodes.

C. Tanase;E. J. Meijer;E. J. Meijer;P. W. M. Blom;D. M. de Leeuw

986
Citations
Poly(diketopyrrolopyrrole−terthiophene) for Ambipolar Logic and Photovoltaics

JC Johan Bijleveld;AP Arjan Zoombelt;Sgj Simon Mathijssen;MM Martijn Wienk

898
Citations
Field-effect transistors made from solution-processed organic semiconductors

A.R. Brown;C.P. Jarrett;D.M. de Leeuw;M. Matters

868
Citations
Towards molecular electronics with large-area molecular junctions

Hylke B. Akkerman;Paul W. M. Blom;Dago M. de Leeuw;Bert de Boer

796
Citations
Plastic transistors in active-matrix displays

H. E. A. Huitema;G. H. Gelinck;J. B. P. H. van der Putten;K. E. Kuijk

768
Citations
A 13.56-MHz RFID System Based on Organic Transponders

E. Cantatore;T.C.T. Geuns;G.H. Gelinck;E. van Veenendaal

724
Citations
Spatially correlated charge transport in organic thin film transistors

Franco Dinelli;Mauro Murgia;Pablo Levy;Massimiliano Cavallini

720
Citations
High-performance all-polymer integrated circuits

G. H. Gelinck;T. C. T. Geuns;D. M. de Leeuw

678
Citations
Logic Gates Made from Polymer Transistors and Their Use in Ring Oscillators

A. R. Brown;A. Pomp;C. M. Hart;D. M. de Leeuw

675
Citations
Plastic transistors in active-matrix displays

E. Huitema;G. Gelinck;B. van der Putten;E. Cantatore

670
Citations
Organic Nonvolatile Memory Devices Based on Ferroelectricity

Ronald C. G. Naber;Kamal Asadi;Paul W. M. Blom;Dago M. de Leeuw

667
Citations
Bottom-up organic integrated circuits

Edsger C. P. Smits;Simon G. J. Mathijssen;Paul A. van Hal;Sepas Setayesh

481
Citations
Low-cost all-polymer integrated circuits

C.M. Hart;D.M. de Leeuw;M. Matters;P.T. Herwig

29
Citations