Julian Pries
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Explore the profile of Julian Pries including associated specialties, affiliations and a list of published articles.
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10
Citations
42
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Recent Articles
1.
Conrads L, Hessler A, Volkel L, Wilden K, Strauch A, Pries J, et al.
ACS Nano
. 2023 Dec;
17(24):25721-25730.
PMID: 38085927
Phase-change materials (PCMs) have been established as prime candidates for nonvolatile resonance tuning of nanophotonic components based on a large optical contrast between their amorphous and crystalline states. Recently, the...
2.
Stenz C, Pries J, Surta T, Gaultois M, Wuttig M
Adv Sci (Weinh)
. 2023 Nov;
10(36):e2304323.
PMID: 37908162
Glasses frequently reveal structural relaxation that leads to changes in their physical properties including enthalpy, specific volume, and resistivity. Analyzing the short-range order (SRO) obtained from electron diffraction by transmission...
3.
Lucas P, Takeda W, Pries J, Benke-Jacob J, Wuttig M
J Chem Phys
. 2023 Feb;
158(5):054502.
PMID: 36754790
Many phase change materials (PCMs) are found to crystallize without exhibiting a glass transition endotherm upon reheating. In this paper, we review experimental evidence revealing that these PCMs and likely...
4.
Cheng Y, Yang Q, Wang J, Dimitriadis T, Schumacher M, Zhang H, et al.
Nat Commun
. 2022 Nov;
13(1):7352.
PMID: 36446781
In glasses, secondary (β-) relaxations are the predominant source of atomic dynamics. Recently, they have been discovered in covalently bonded glasses, i.e., amorphous phase-change materials (PCMs). However, it is unclear...
5.
Gladisch F, Pippinger T, Meyer J, Pries J, Richter J, Steinberg S
Inorg Chem
. 2022 Jun;
61(24):9269-9282.
PMID: 35667003
In the quest for materials addressing the grand challenges of the future, there is a critical need for a broad understanding of their electronic structures because the knowledge of the...
6.
Barnett J, Wehmeier L, Hessler A, Lewin M, Pries J, Wuttig M, et al.
Nano Lett
. 2021 Oct;
21(21):9012-9020.
PMID: 34665620
Chalcogenide phase change materials reversibly switch between non-volatile states with vastly different optical properties, enabling novel active nanophotonic devices. However, a fundamental understanding of their laser-switching behavior is lacking and...
7.
Persch C, Muller M, Yadav A, Pries J, Honne N, Kerres P, et al.
Nat Commun
. 2021 Aug;
12(1):4978.
PMID: 34404800
Controlling a state of material between its crystalline and glassy phase has fostered many real-world applications. Nevertheless, design rules for crystallization and vitrification kinetics still lack predictive power. Here, we...
8.
Peng S, Cheng Y, Pries J, Wei S, Yu H, Wuttig M
Sci Adv
. 2020 Jan;
6(2):eaay6726.
PMID: 31950085
Relaxation processes are decisive for many physical properties of amorphous materials. For amorphous phase-change materials (PCMs) used in nonvolatile memories, relaxation processes are, however, difficult to characterize because of the...
9.
Pries J, Wei S, Wuttig M, Lucas P
Adv Mater
. 2019 Aug;
31(39):e1900784.
PMID: 31385632
Controlling crystallization kinetics is key to overcome the temperature-time dilemma in phase change materials employed for data storage. While the amorphous phase must be preserved for more than 10 years...
10.
Michel A, Hessler A, Meyer S, Pries J, Yu Y, Kalix T, et al.
Adv Mater
. 2019 May;
31(29):e1901033.
PMID: 31131947
Nanometer-thick active metasurfaces (MSs) based on phase-change materials (PCMs) enable compact photonic components, offering adjustable functionalities for the manipulation of light, such as polarization filtering, lensing, and beam steering. Commonly,...