Daniil Karnaushenko
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Explore the profile of Daniil Karnaushenko including associated specialties, affiliations and a list of published articles.
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42
Citations
508
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Recent Articles
1.
Zhang W, Tang H, Yan Y, Ma J, Ferro L, Merces L, et al.
ACS Appl Energy Mater
. 2024 Dec;
7(24):11256-11268.
PMID: 39734918
Transforming thin films into high-order stacks has proven effective for robust energy storage in macroscopic configurations like cylindrical, prismatic, and pouch cells. However, the lack of tools at the submillimeter...
2.
Fedorov P, Soldatov I, Neu V, Schafer R, Schmidt O, Karnaushenko D
Nat Commun
. 2024 Apr;
15(1):3538.
PMID: 38671002
No abstract available.
3.
Fedorov P, Soldatov I, Neu V, Schafer R, Schmidt O, Karnaushenko D
Nat Commun
. 2024 Mar;
15(1):2048.
PMID: 38448405
Modification of the magnetic properties under the induced strain and curvature is a promising avenue to build three-dimensional magnetic devices, based on the domain wall motion. So far, most of...
4.
Merces L, Ferro L, Thomas A, Karnaushenko D, Luo Y, Egunov A, et al.
Adv Mater
. 2024 Feb;
36(26):e2313327.
PMID: 38402420
Choreographing the adaptive shapes of patterned surfaces to exhibit designable mechanical interactions with their environment remains an intricate challenge. Here, a novel category of strain-engineered dynamic-shape materials, empowering diverse multi-dimensional...
5.
Qu Z, Ma J, Huang Y, Li T, Tang H, Wang X, et al.
Adv Mater
. 2024 Jan;
36(15):e2310667.
PMID: 38232386
Zn batteries show promise for microscale applications due to their compatibility with air fabrication but face challenges like dendrite growth and chemical corrosion, especially at the microscale. Despite previous attempts...
6.
Microelectronic Morphogenesis: Smart Materials with Electronics Assembling into Artificial Organisms
McCaskill J, Karnaushenko D, Zhu M, Schmidt O
Adv Mater
. 2023 Oct;
35(51):e2306344.
PMID: 37814374
Microelectronic morphogenesis is the creation and maintenance of complex functional structures by microelectronic information within shape-changing materials. Only recently has in-built information technology begun to be used to reshape materials...
7.
Luo Y, Reza Abidian M, Ahn J, Akinwande D, Andrews A, Antonietti M, et al.
ACS Nano
. 2023 Mar;
17(6):5211-5295.
PMID: 36892156
Humans rely increasingly on sensors to address grand challenges and to improve quality of life in the era of digitalization and big data. For ubiquitous sensing, flexible sensors are developed...
8.
Singh B, Ravishankar R, Otalora J, Soldatov I, Schafer R, Karnaushenko D, et al.
Nanoscale
. 2022 Sep;
14(37):13667-13678.
PMID: 36082910
Linear oscillatory motion of domain walls (DWs) in the kHz and MHz regime is crucial when realizing precise magnetic field sensors such as giant magnetoimpedance devices. Numerous magnetically active defects...
9.
Becker C, Bao B, Karnaushenko D, Bandari V, Rivkin B, Li Z, et al.
Nat Commun
. 2022 Apr;
13(1):2121.
PMID: 35440595
Magnetic sensors are widely used in our daily life for assessing the position and orientation of objects. Recently, the magnetic sensing modality has been introduced to electronic skins (e-skins), enabling...
10.
Rivkin B, Becker C, Singh B, Aziz A, Akbar F, Egunov A, et al.
Sci Adv
. 2021 Dec;
7(51):eabl5408.
PMID: 34919439
Existing electronically integrated catheters rely on the manual assembly of separate components to integrate sensing and actuation capabilities. This strongly impedes their miniaturization and further integration. Here, we report an...