Publications
18
Citations
727
Est. group size
—
Recurring co-author estimate
Active years
8
Publishing since 2017
Jocelyn T. L. Gamler's research focuses on designing nanoscale metal particles used as electrocatalysts, which speed up the chemical reactions needed for energy conversion technologies like fuel cells. A key part of this work involves controlling the shape, structure, and atomic strain of core-shell and multimetallic nanoparticles, and using advanced electron microscopy techniques to measure these features precisely. More recent work also includes chemistry education and demonstration activities.
Publication activity was most concentrated around 2019-2020, followed by a gap and a smaller number of outputs in 2023-2024, indicating a slowing overall cadence.
Generated by claude-opus-4-8 from public bibliographic data · Jul 11, 2026
- A Chemistry Demonstration Show in Three Parts
The Chemical Educator · 2023
- A Chemistry Demonstration Show in Three Parts
The Chemical Educator · 2023
- A Chemistry Demonstration Show in Three Parts
The Chemical Educator · 2023
- Lattice Strain Measurement of Core@Shell Electrocatalysts with 4D Scanning Transmission Electron Microscopy Nanobeam Electron Diffraction
ACS Catalysis · 2020
- Ligand‐Guided Growth of Alloyed Shells on Intermetallic Seeds as a Route toward Multimetallic Nanocatalysts with Shape‐Control
ChemNanoMat · 2020
- Lattice strain measurement of core@shell Rh@Pt nanoparticle electrocatalysts with 4D-STEM nanobeam electron diffraction
arXiv (Cornell University) · 2020
- Particle1_4DSTEM.json
Figshare · 2020
- Alkene Hydrosilylation on Oxide‐Supported Pt‐Ligand Single‐Site Catalysts
ChemCatChem · 2019
- Integration of Sequential Reactions in a Continuous Flow Droplet Reactor: A Route to Architecturally Defined Bimetallic Nanostructures
Particle & Particle Systems Characterization · 2019
- Investigation of Strain in Core@shell Electrocatalysts with ADF-STEM and 4D STEM Scanning Nanodiffraction
Microscopy and Microanalysis · 2019
- Facet-Dependent Deposition of Highly Strained Alloyed Shells on Intermetallic Nanoparticles for Enhanced Electrocatalysis
Nano Letters · 2017
- The Chemical Educator×3
- Nano Letters×2
- ACS Nano×2
- Advanced Materials×1
- Nanoscale Advances×1
This profile was generated automatically from public scholarly data (OpenAlex). Group size and activity levels are estimates derived from co-authorship patterns.
Last updated Jul 11, 2026.
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