Nathan J Szymanski
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Explore the profile of Nathan J Szymanski including associated specialties, affiliations and a list of published articles.
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9
Citations
56
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Recent Articles
1.
Liu F, Szymanski N, Noordhoek K, Shin H, Kim D, Bartel C, et al.
Nano Lett
. 2024 Dec;
25(1):299-305.
PMID: 39729044
Rutile GeO and related materials are attracting interest due to their ultrawide band gaps and potential for ambipolar doping in high-power electronic applications. This study examines the growth of rutile...
2.
Chen Y, Zhao X, Chen K, Koirala K, Giovine R, Yang X, et al.
Adv Mater
. 2024 Dec;
37(7):e2416342.
PMID: 39713900
Rationalizing synthetic pathways is crucial for material design and property optimization, especially for polymorphic and metastable phases. Over-stoichiometric rocksalt (ORX) compounds, characterized by their face-sharing configurations, are a promising group...
3.
Wang S, Szymanski N, Fei Y, Dong W, Christensen J, Zeng Y, et al.
Inorg Chem
. 2024 Jul;
63(29):13576-13584.
PMID: 38981128
With increasing battery demand comes a need for diversified Li sources beyond brines. Among all Li-bearing minerals, spodumene is most often used for its high Li content and natural abundance....
4.
Szymanski N, Byeon Y, Sun Y, Zeng Y, Bai J, Kunz M, et al.
Sci Adv
. 2024 Jul;
10(27):eadp3309.
PMID: 38959320
The success of solid-state synthesis often hinges on the first intermediate phase that forms, which determines the remaining driving force to produce the desired target material. Recent work suggests that...
5.
Zeng Y, Szymanski N, He T, Jun K, Gallington L, Huo H, et al.
Sci Adv
. 2024 Jan;
10(3):eadj5431.
PMID: 38232170
Metastable polymorphs often result from the interplay between thermodynamics and kinetics. Despite advances in predictive synthesis for solution-based techniques, there remains a lack of methods to design solid-state reactions targeting...
6.
Szymanski N, Rendy B, Fei Y, Kumar R, He T, Milsted D, et al.
Nature
. 2023 Nov;
624(7990):86-91.
PMID: 38030721
To close the gap between the rates of computational screening and experimental realization of novel materials, we introduce the A-Lab, an autonomous laboratory for the solid-state synthesis of inorganic powders....
7.
Szymanski N, Nevatia P, Bartel C, Zeng Y, Ceder G
Nat Commun
. 2023 Nov;
14(1):6956.
PMID: 37907493
Solid-state synthesis plays an important role in the development of new materials and technologies. While in situ characterization and ab-initio computations have advanced our understanding of materials synthesis, experiments targeting...
8.
Szymanski N, Zeng Y, Huo H, Bartel C, Kim H, Ceder G
Mater Horiz
. 2021 Nov;
8(8):2169-2198.
PMID: 34846423
Autonomous experimentation driven by artificial intelligence (AI) provides an exciting opportunity to revolutionize inorganic materials discovery and development. Herein, we review recent progress in the design of self-driving laboratories, including...
9.
Szymanski N, Walters L, Puggioni D, Rondinelli J
Phys Rev Lett
. 2019 Dec;
123(23):236402.
PMID: 31868440
Using a first-principles approach, we design the heteroanionic oxynitride MoON to exhibit a first-order isosymmetric thermally activated Peierls-type metal-insulator transition (MIT). We identify a ground state insulating phase (α-MoON) with...