Pooja Goddard

539 total citations
24 papers, 412 citations indexed

About

Pooja Goddard is a scholar working on Electrical and Electronic Engineering, Materials Chemistry and Atomic and Molecular Physics, and Optics. According to data from OpenAlex, Pooja Goddard has authored 24 papers receiving a total of 412 indexed citations (citations by other indexed papers that have themselves been cited), including 18 papers in Electrical and Electronic Engineering, 16 papers in Materials Chemistry and 2 papers in Atomic and Molecular Physics, and Optics. Recurrent topics in Pooja Goddard's work include Advanced Battery Materials and Technologies (10 papers), Advancements in Battery Materials (8 papers) and Chalcogenide Semiconductor Thin Films (7 papers). Pooja Goddard is often cited by papers focused on Advanced Battery Materials and Technologies (10 papers), Advancements in Battery Materials (8 papers) and Chalcogenide Semiconductor Thin Films (7 papers). Pooja Goddard collaborates with scholars based in United Kingdom, Germany and United States. Pooja Goddard's co-authors include Stephen R. Yeandel, Peter R. Slater, Roger Smith, Bo Dong, Michael J. Watts, John M. Walls, P. D. Hatton, Ali Abbas, Ying Zhou and Ryan Sharpe and has published in prestigious journals such as Advanced Materials, Nature Communications and The Journal of Chemical Physics.

In The Last Decade

Pooja Goddard

24 papers receiving 398 citations

Peers

Pooja Goddard
Bowen Fu China
Nan Dong China
J. D. Kephart United States
Bonho Koo South Korea
В. С. Первов Russia
А. А. Расковалов Russia
Yilong Pan China
Leila Costelle Finland
Akitoshi Suzumura Japan
Baltej Singh India
Bowen Fu China
Pooja Goddard
Citations per year, relative to Pooja Goddard Pooja Goddard (= 1×) peers Bowen Fu

Countries citing papers authored by Pooja Goddard

Since Specialization
Citations

This map shows the geographic impact of Pooja Goddard's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Pooja Goddard with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Pooja Goddard more than expected).

Fields of papers citing papers by Pooja Goddard

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Pooja Goddard. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Pooja Goddard. The network helps show where Pooja Goddard may publish in the future.

Co-authorship network of co-authors of Pooja Goddard

This figure shows the co-authorship network connecting the top 25 collaborators of Pooja Goddard. A scholar is included among the top collaborators of Pooja Goddard based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Pooja Goddard. Pooja Goddard is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Dong, Bo, Linhao Li, Pengcheng Zhu, et al.. (2024). Experimental and computational study of Zn doping in Li5+xLa3Nb2−xZrxO12 garnet solid state electrolytes. Materials Advances. 5(16). 6648–6660. 2 indexed citations
2.
Mukherjee, Shriparna, David Voneshen, Andrew Ian Duff, et al.. (2023). Beyond Rattling: Tetrahedrites as Incipient Ionic Conductors. Advanced Materials. 35(44). e2306088–e2306088. 4 indexed citations
3.
Zhou, Ying, Prashanth Srinivasan, Fritz Körmann, et al.. (2022). Thermodynamics up to the melting point in a TaVCrW high entropy alloy: Systematic ab initio study aided by machine learning potentials. Physical review. B.. 105(21). 28 indexed citations
4.
Zhou, Ying, et al.. (2022). Atomistic simulation of helium diffusion and clustering in plutonium dioxide. Physical Chemistry Chemical Physics. 24(35). 20709–20720. 7 indexed citations
5.
Hatton, P. D., Michael J. Watts, Ying Zhou, Roger Smith, & Pooja Goddard. (2022). Arsenic doping and diffusion in CdTe: a DFT study of bulk and grain boundaries. Journal of Physics Condensed Matter. 35(7). 75702–75702. 3 indexed citations
6.
Dong, Bo, Stephen R. Yeandel, Jingwei Xiu, et al.. (2022). Halogenation of Li7La3Zr2O12 solid electrolytes: a combined solid-state NMR, computational and electrochemical study. Journal of Materials Chemistry A. 10(20). 11172–11185. 13 indexed citations
7.
Ghosh, P. S., A. Arya, Ying Zhou, et al.. (2022). Design principles of low-activation high entropy alloys. Journal of Alloys and Compounds. 907. 164526–164526. 27 indexed citations
8.
Neale, Alex R., Ryan Sharpe, Stephen R. Yeandel, et al.. (2021). Design Parameters for Ionic Liquid–Molecular Solvent Blend Electrolytes to Enable Stable Li Metal Cycling Within Li–O2 Batteries. Advanced Functional Materials. 31(27). 22 indexed citations
9.
Watts, Michael J., P. D. Hatton, Roger Smith, et al.. (2021). Chlorine passivation of grain boundaries in cadmium telluride solar cells. Physical Review Materials. 5(3). 17 indexed citations
10.
Hatton, P. D., Michael J. Watts, Ali Abbas, et al.. (2021). Chlorine activated stacking fault removal mechanism in thin film CdTe solar cells: the missing piece. Nature Communications. 12(1). 4938–4938. 25 indexed citations
11.
Goddard, Pooja, et al.. (2021). The role of excited-state character, structural relaxation, and symmetry breaking in enabling delayed fluorescence activity in push–pull chromophores. Physical Chemistry Chemical Physics. 23(46). 26135–26150. 14 indexed citations
12.
Kelly, Paul F., et al.. (2021). Mechanistic insight into the fluorescence activity of forensic fingerprinting reagents. The Journal of Chemical Physics. 154(12). 124313–124313. 3 indexed citations
13.
Slater, Peter R., et al.. (2020). Carbon dioxide and water incorporation mechanisms in SrFeO3−δ phases: a computational study. Physical Chemistry Chemical Physics. 22(43). 25146–25155. 5 indexed citations
14.
Amores, Marco, Hany El‐Shinawi, Innes McClelland, et al.. (2020). Li1.5La1.5MO6 (M = W6+, Te6+) as a new series of lithium-rich double perovskites for all-solid-state lithium-ion batteries. Nature Communications. 11(1). 6392–6392. 44 indexed citations
15.
Hatton, P. D., Ali Abbas, Piotr Kamiński, et al.. (2020). Inert gas bubble formation in magnetron sputtered thin-film CdTe solar cells. Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences. 476(2239). 20200056–20200056. 12 indexed citations
16.
Koketsu, Toshinari, Jiwei Ma, Benjamin J. Morgan, et al.. (2019). Exploiting cationic vacancies for increased energy densities in dual-ion batteries. Energy storage materials. 25. 154–163. 19 indexed citations
17.
Watts, Michael J., Thomas Fiducia, Biplab Sanyal, et al.. (2019). Enhancement of photovoltaic efficiency in CdSe x Te 1− x (where 0 ⩽ x ⩽ 1): insights from density functional theory. Journal of Physics Condensed Matter. 32(12). 125702–125702. 18 indexed citations
18.
Dong, Bo, Stephen R. Yeandel, Pooja Goddard, & Peter R. Slater. (2019). Combined Experimental and Computational Study of Ce-Doped La3Zr2Li7O12 Garnet Solid-State Electrolyte. Chemistry of Materials. 32(1). 215–223. 50 indexed citations
19.
Hatton, P. D., et al.. (2019). Inert gas cluster formation in sputter-deposited thin film CdTe solar cells. Thin Solid Films. 692. 137614–137614. 5 indexed citations
20.
Yeandel, Stephen R., David O. Scanlon, & Pooja Goddard. (2019). Enhanced Li-ion dynamics in trivalently doped lithium phosphidosilicate Li2SiP2: a candidate material as a solid Li electrolyte. Journal of Materials Chemistry A. 7(8). 3953–3961. 11 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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