In-situ visualization of solute-driven phase coexistence within individual nanorods

In-situ visualization of solute-driven phase coexistence within individual nanorods

Compared to thin films and other geometries, nanorods can exhibit particularly high performance in solute-intercalation-based energy and information storage devices. Here, the authors use in situ electron microscopy and spectroscopy to study the hydrogenation of palladium nanorods, revealing relatio...

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Main Authors: Fariah Hayee, Tarun C. Narayan, Neel Nadkarni, Andrea Baldi, Ai Leen Koh, Martin Z. Bazant, Robert Sinclair, Jennifer A. Dionne
Format: Article
Language:English
Published: Nature Publishing Group 2018-05-01
Series:Nature Communications
Online Access:https://doi.org/10.1038/s41467-018-04021-1
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spelling doaj-7163acc388614c85a6ffe6ebd7fc24c92021-05-11T10:32:40ZengNature Publishing GroupNature Communications2041-17232018-05-01911810.1038/s41467-018-04021-1In-situ visualization of solute-driven phase coexistence within individual nanorodsFariah Hayee0Tarun C. Narayan1Neel Nadkarni2Andrea Baldi3Ai Leen Koh4Martin Z. Bazant5Robert Sinclair6Jennifer A. Dionne7Department of Electrical Engineering, Stanford UniversityDepartment of Materials Science and Engineering, Stanford UniversityDepartment of Chemical Engineering, Massachusetts Institute of TechnologyDIFFER - Dutch Institute for Fundamental Energy ResearchStanford Nano Shared Facilities, Stanford UniversityDepartment of Chemical Engineering, Massachusetts Institute of TechnologyDepartment of Materials Science and Engineering, Stanford UniversityDepartment of Materials Science and Engineering, Stanford UniversityCompared to thin films and other geometries, nanorods can exhibit particularly high performance in solute-intercalation-based energy and information storage devices. Here, the authors use in situ electron microscopy and spectroscopy to study the hydrogenation of palladium nanorods, revealing relationships between nanorod structure and device cyclability and capacity.https://doi.org/10.1038/s41467-018-04021-1
collection DOAJ
language English
format Article
sources DOAJ
author Fariah Hayee
Tarun C. Narayan
Neel Nadkarni
Andrea Baldi
Ai Leen Koh
Martin Z. Bazant
Robert Sinclair
Jennifer A. Dionne
spellingShingle Fariah Hayee
Tarun C. Narayan
Neel Nadkarni
Andrea Baldi
Ai Leen Koh
Martin Z. Bazant
Robert Sinclair
Jennifer A. Dionne
In-situ visualization of solute-driven phase coexistence within individual nanorods
Nature Communications
author_facet Fariah Hayee
Tarun C. Narayan
Neel Nadkarni
Andrea Baldi
Ai Leen Koh
Martin Z. Bazant
Robert Sinclair
Jennifer A. Dionne
author_sort Fariah Hayee
title In-situ visualization of solute-driven phase coexistence within individual nanorods
title_short In-situ visualization of solute-driven phase coexistence within individual nanorods
title_full In-situ visualization of solute-driven phase coexistence within individual nanorods
title_fullStr In-situ visualization of solute-driven phase coexistence within individual nanorods
title_full_unstemmed In-situ visualization of solute-driven phase coexistence within individual nanorods
title_sort in-situ visualization of solute-driven phase coexistence within individual nanorods
publisher Nature Publishing Group
series Nature Communications
issn 2041-1723
publishDate 2018-05-01
description Compared to thin films and other geometries, nanorods can exhibit particularly high performance in solute-intercalation-based energy and information storage devices. Here, the authors use in situ electron microscopy and spectroscopy to study the hydrogenation of palladium nanorods, revealing relationships between nanorod structure and device cyclability and capacity.
url https://doi.org/10.1038/s41467-018-04021-1
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