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
11.
Neu V, Soldatov I, Schafer R, Karnaushenko D, Mirhajivarzaneh A, Karnaushenko D, et al.
Nano Lett
. 2021 Nov;
21(23):9889-9895.
PMID: 34807625
The functionality of a ferroic device is intimately coupled to the configuration of domains, domain boundaries, and the possibility for tailoring them. Exemplified with a ferromagnetic system, we present a...
12.
Akbar F, Rivkin B, Aziz A, Becker C, Karnaushenko D, Medina-Sanchez M, et al.
Sci Adv
. 2021 Oct;
7(44):eabj0767.
PMID: 34705511
Oscillations at several hertz are a key feature of dynamic behavior of various biological entities, such as the pulsating heart, firing neurons, or the sperm-beating flagellum. Inspired by nature’s fundamental...
13.
Li F, Wang J, Liu L, Qu J, Li Y, Bandari V, et al.
Adv Sci (Weinh)
. 2021 Oct;
8(20):e2103927.
PMID: 34672121
No abstract available.
14.
Lepucki P, Dioguardi A, Karnaushenko D, Schmidt O, Grafe H
J Magn Reson
. 2021 Oct;
332:107077.
PMID: 34634649
We derive the normalized limit of detection for frequency space (nLOD) as a parameter to measure the sensitivity of an NMR spectroscopy setup. nLOD is independent of measurement settings such...
15.
Lee Y, Bandari V, Li Z, Medina-Sanchez M, Maitz M, Karnaushenko D, et al.
Nat Commun
. 2021 Aug;
12(1):4967.
PMID: 34426576
Today's smallest energy storage devices for in-vivo applications are larger than 3 mm and lack the ability to continuously drive the complex functions of smart dust electronic and microrobotic systems....
16.
Bao B, Rivkin B, Akbar F, Karnaushenko D, Bandari V, Teuerle L, et al.
Adv Mater
. 2021 May;
33(26):e2101272.
PMID: 34028906
Many modern electronic applications rely on functional units arranged in an active-matrix integrated on a single chip. The active-matrix allows numerous identical device pixels to be addressed within a single...
17.
Ge J, Zhu M, Eisner E, Yin Y, Dong H, Karnaushenko D, et al.
Small
. 2021 May;
17(24):e2101704.
PMID: 33977641
Imperceptible electronics will make next-generation healthcare and biomedical systems thinner, lighter, and more flexible. While other components are thoroughly investigated, imperceptible energy storage devices lag behind because the decrease of...
18.
Egunov A, Dou Z, Karnaushenko D, Hebenstreit F, Kretschmann N, Akgun K, et al.
Small
. 2021 Jan;
17(5):e2002549.
PMID: 33448115
Analytical platforms based on impedance spectroscopy are promising for non-invasive and label-free analysis of single cells as well as of their extracellular matrix, being essential to understand cell function in...
19.
Zhu M, Hu J, Lu Q, Dong H, Karnaushenko D, Becker C, et al.
Adv Mater
. 2021 Jan;
33(8):e2007497.
PMID: 33448064
Owing to their high safety and reversibility, aqueous microbatteries using zinc anodes and an acid electrolyte have emerged as promising candidates for wearable electronics. However, a critical limitation that prevents...
20.
Saggau C, Gabler F, Karnaushenko D, Karnaushenko D, Ma L, Schmidt O
Adv Mater
. 2020 Jul;
32(37):e2003252.
PMID: 32686201
Mechanical strain formed at the interfaces of thin films has been widely applied to self-assemble 3D microarchitectures. Among them, rolled-up microtubes possess a unique 3D geometry beneficial for working as...