Michael Aling
University of California, Santa Barbara
6 Papers
19 Citations
Michael Aling is an academic researcher from University of California, Santa Barbara. The author has contributed to research in topics: Energy (signal processing) & Coupling (probability). The author has an hindex of 3, co-authored 4 publications.
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Papers
Magnetically driven band shift and metal-insulator transition in spin-orbit-coupled S r 3 ( I r 1 − x R u x ) 2 O 7
S.Y. Song,Sang Wook Kim,G. H. Ahn,Jungyoon Seo,Julian L. Schmehr,Michael Aling,Stephen D. Wilson,Yeongkwan Kim,S. J. Moon +8 more
TL;DR: In this article, a combined infrared and angle-resolved photoemission study of the electronic response of three compounds was performed, and it was shown that the temperature-induced metal-insulator transition of the three compounds exhibits the characteristic feature of the effective total angular momentum of the antiferromagnetic Mott state.
9
High-pressure laser floating zone furnace
TL;DR: This work demonstrates a novel high-pressure laser-based floating zone system (HP-LFZ), permitting greatly enhanced processing pressures over conventional mirror-based designs, with the current design allowing for pressures up to 1000 bar.
8
Overdamped Antiferromagnetic Strange Metal State in Sr_{3}IrRuO_{7}.
Julian L. Schmehr,Thomas R. Mion,Zach Porter,Michael Aling,Huibo Cao,Mary Upton,Zahirul Islam,Ruihua He,Rajdeep Sensarma,Nandini Trivedi,Stephen D. Wilson +10 more
TL;DR: In this paper, the anomalously large energy scale of the ground state of the electron was investigated via resonant x-ray scattering and angle-resolved photo-emission measurements.
7
Evaluation and Comparison of Reversible Water Electrolysis as a Means for Pneumatic Actuation
Kristan M. Hilby,Peter Beaumont Morice,Michael Aling,Ian W. Hunter +3 more
- 03 Apr 2023
TL;DR: In this article , reversible water electrolysis was used as a method for pneumatic actuation via the electrochemical decomposition of water into hydrogen and oxygen gas, and the achievable pressure was shown to be at least 0.75 MPa with a flow rate of 0.06 [L/min].
Advances in high-pressure laser floating zone growth: The Laser Optical Kristallmacher II (LOKII).
Steven J Gomez Alvarado,Eli Zoghlin,Azzedin R. Jackson,Linus Kautzsch,Jayden C. Plumb,Michael Aling,Andrea N. Capa Salinas,Ganesh Pokharel,Yiming Pang,Reina M. Gomez,Samantha Daly,Stephen D. Wilson +11 more
TL;DR: High-pressure laser floating zone growth technique using the Laser Optical Kristallmacher II (LOKII) furnace enables the growth of new volatile and metastable phases under pressures up to 700 bar.