Martin Kaltenbrunner
Martin Kaltenbrunner
Soft Matter Physics and LIT Soft Materials Lab, Johannes Kepler University Linz
Verified email at - Homepage
Cited by
Cited by
An ultra-lightweight design for imperceptible plastic electronics
M Kaltenbrunner, T Sekitani, J Reeder, T Yokota, K Kuribara, T Tokuhara, ...
Nature 499 (7459), 458-463, 2013
Ultrathin and lightweight organic solar cells with high flexibility
M Kaltenbrunner, MS White, ED Głowacki, T Sekitani, T Someya, ...
Nature communications 3 (1), 770, 2012
Ultraflexible organic photonic skin
T Yokota, P Zalar, M Kaltenbrunner, H Jinno, N Matsuhisa, H Kitanosako, ...
Science advances 2 (4), e1501856, 2016
Flexible high power-per-weight perovskite solar cells with chromium oxide–metal contacts for improved stability in air
M Kaltenbrunner, G Adam, ED Głowacki, M Drack, R Schw÷diauer, ...
Nature materials 14 (10), 1032-1039, 2015
Ultrathin, highly flexible and stretchable PLEDs
MS White, M Kaltenbrunner, ED Głowacki, K Gutnichenko, G Kettlgruber, ...
Nature Photonics 7 (10), 811-816, 2013
25th anniversary article: a soft future: from robots and sensor skin to energy harvesters
S Bauer, S Bauer‐Gogonea, I Graz, M Kaltenbrunner, C Keplinger, ...
Advanced Materials 26 (1), 149-162, 2014
Printable elastic conductors with a high conductivity for electronic textile applications
N Matsuhisa, M Kaltenbrunner, T Yokota, H Jinno, K Kuribara, T Sekitani, ...
Nature communications 6 (1), 7461, 2015
Instant tough bonding of hydrogels for soft machines and electronics
D Wirthl, R Pichler, M Drack, G Kettlguber, R Moser, R Gerstmayr, ...
Science advances 3 (6), e1700053, 2017
Ultraflexible, large-area, physiological temperature sensors for multipoint measurements
T Yokota, Y Inoue, Y Terakawa, J Reeder, M Kaltenbrunner, T Ware, ...
Proceedings of the National Academy of Sciences 112 (47), 14533-14538, 2015
Resilient yet entirely degradable gelatin-based biogels for soft robots and electronics
M Baumgartner, F Hartmann, M Drack, D Preninger, D Wirthl, R Gerstmayr, ...
Nature Materials 19 (10), 1102-1109, 2020
R÷ntgen’s electrode-free elastomer actuators without electromechanical pull-in instability
C Keplinger, M Kaltenbrunner, N Arnold, S Bauer
Proceedings of the National Academy of Sciences 107 (10), 4505-4510, 2010
Wearable magnetic field sensors for flexible electronics
M Melzer, JI M÷nch, D Makarov, Y Zabila, GS Ca˝ˇn Berm˙dez, ...
Advanced Materials 27 (7), 1274-1280, 2015
Hydrogen‐bonded semiconducting pigments for air‐stable field‐effect transistors
ED Głowacki, M Irimia‐Vladu, M Kaltenbrunner, J Gsiorowski, MS White, ...
Advanced Materials 25 (11), 1563-1569, 2013
Imperceptible magnetoelectronics
M Melzer, M Kaltenbrunner, D Makarov, D Karnaushenko, ...
Nature communications 6 (1), 6080, 2015
A bimodal soft electronic skin for tactile and touchless interaction in real time
J Ge, X Wang, M Drack, O Volkov, M Liang, GS Ca˝ˇn Berm˙dez, R Illing, ...
Nature communications 10 (1), 4405, 2019
Flexible ferroelectret field-effect transistor for large-area sensor skins and microphones
I Graz, M Kaltenbrunner, C Keplinger, R Schw÷diauer, S Bauer, ...
Applied physics letters 89 (7), 2006
Ultraflexible organic amplifier with biocompatible gel electrodes
T Sekitani, T Yokota, K Kuribara, M Kaltenbrunner, T Fukushima, Y Inoue, ...
Nature communications 7 (1), 11425, 2016
Stretchable batteries: Arrays of ultracompliant electrochemical dry gel cells for stretchable electronics (Adv. Mater. 18/2010)
M Kaltenbrunner, G Kettlgruber, C Siket, R Schw÷diauer, S Bauer
Advanced materials 22 (18), 2010
Mechanically adaptive organic transistors for implantable electronics.
J Reeder, M Kaltenbrunner, T Ware, D Arreaga-Salas, ...
Advanced Materials (Deerfield Beach, Fla.) 26 (29), 4967-4973, 2014
An imperceptible plastic electronic wrap
M Drack, I Graz, T Sekitani, T Someya, M Kaltenbrunner, S Bauer
Advanced Materials 27 (1), 34-40, 2015
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