Peter Lamp

9.6k total citations · 6 hit papers
39 papers, 8.2k citations indexed

About

Peter Lamp is a scholar working on Electrical and Electronic Engineering, Automotive Engineering and Materials Chemistry. According to data from OpenAlex, Peter Lamp has authored 39 papers receiving a total of 8.2k indexed citations (citations by other indexed papers that have themselves been cited), including 29 papers in Electrical and Electronic Engineering, 17 papers in Automotive Engineering and 8 papers in Materials Chemistry. Recurrent topics in Peter Lamp's work include Advancements in Battery Materials (25 papers), Advanced Battery Materials and Technologies (23 papers) and Advanced Battery Technologies Research (17 papers). Peter Lamp is often cited by papers focused on Advancements in Battery Materials (25 papers), Advanced Battery Materials and Technologies (23 papers) and Advanced Battery Technologies Research (17 papers). Peter Lamp collaborates with scholars based in Germany, United States and Italy. Peter Lamp's co-authors include Filippo Maglia, Simon Lux, Odysseas Paschos, Yang Shao‐Horn, Livia Giordano, Chong Seung Yoon, Saskia Lupart, Hao-Hsun Chang, Yang‐Kook Sun and Nir Pour and has published in prestigious journals such as Chemical Reviews, Physical review. B, Condensed matter and Energy & Environmental Science.

In The Last Decade

Peter Lamp

38 papers receiving 8.1k citations

Hit Papers

Inorganic Solid-State Electrolytes for Lithium Batteries:... 2015 2026 2018 2022 2015 2016 2015 2015 2015 500 1000 1.5k 2.0k
What are hit papers?

Hit papers significantly outperform the citation benchmark for their cohort. A paper qualifies if it has ≥500 total citations, achieves ≥1.5× the top-1% citation threshold for papers in the same subfield and year (this is the minimum needed to enter the top 1%, not the average within it), or reaches the top citation threshold in at least one of its specific research topics.

  1. Inorganic Solid-State Electrolytes for Lithium Batteries: Mechanisms and Properties Governing Ion Conduction
    2015 2.1k citations John Christopher Bachman, Sokseiha Muy et al. profile →
  2. Nickel-Rich Layered Cathode Materials for Automotive Lithium-Ion Batteries: Achievements and Perspectives
    2016 1.2k citations Seung‐Taek Myung, Filippo Maglia et al. ACS Energy Letters profile →
  3. Electrode–Electrolyte Interface in Li-Ion Batteries: Current Understanding and New Insights
    2015 877 citations Livia Giordano, Hao-Hsun Chang et al. profile →
  4. Future generations of cathode materials: an automotive industry perspective
    2015 704 citations Peter Lamp, Simon Lux et al. profile →
  5. Optimizing Areal Capacities through Understanding the Limitations of Lithium-Ion Electrodes
    2015 551 citations Kevin G. Gallagher, Stephen E. Trask et al. Journal of The Electrochemical Society profile →
  6. Degradation Mechanism of Ni-Enriched NCA Cathode for Lithium Batteries: Are Microcracks Really Critical?
    2019 342 citations Kang-Joon Park, Jang‐Yeon Hwang et al. ACS Energy Letters profile →

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
Peter Lamp Germany 25 7.4k 3.7k 1.8k 1.2k 854 39 8.2k
Ruijuan Xiao China 46 7.1k 0.9× 2.2k 0.6× 2.0k 1.1× 1.7k 1.4× 1.0k 1.2× 109 8.0k
Byoungwoo Kang South Korea 28 6.0k 0.8× 1.9k 0.5× 1.8k 1.0× 1.8k 1.5× 888 1.0× 79 6.8k
Xia Cao United States 47 8.2k 1.1× 4.6k 1.2× 1.1k 0.6× 960 0.8× 541 0.6× 99 9.2k
Rachid Yazami France 45 5.9k 0.8× 2.4k 0.7× 1.4k 0.8× 1.5k 1.2× 1.1k 1.2× 140 6.6k
Simon Lux Germany 25 7.1k 0.9× 3.5k 1.0× 1.2k 0.7× 1.0k 0.8× 571 0.7× 57 7.5k
Ira Bloom United States 49 6.6k 0.9× 4.8k 1.3× 827 0.5× 935 0.8× 768 0.9× 157 8.2k
Payam Kaghazchi Germany 39 5.6k 0.8× 2.0k 0.5× 1.5k 0.9× 1.3k 1.0× 833 1.0× 143 6.4k
Glenn G. Amatucci United States 36 6.2k 0.8× 2.0k 0.5× 1.2k 0.7× 1.7k 1.4× 1.1k 1.3× 81 6.9k
Qiuyan Li China 34 11.2k 1.5× 6.8k 1.8× 1.1k 0.6× 1.2k 1.0× 424 0.5× 88 11.8k

Countries citing papers authored by Peter Lamp

Since Specialization
Citations

This map shows the geographic impact of Peter Lamp'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 Peter Lamp with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Peter Lamp more than expected).

Fields of papers citing papers by Peter Lamp

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Peter Lamp. 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 Peter Lamp. The network helps show where Peter Lamp may publish in the future.

Co-authorship network of co-authors of Peter Lamp

This figure shows the co-authorship network connecting the top 25 collaborators of Peter Lamp. A scholar is included among the top collaborators of Peter Lamp 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 Peter Lamp. Peter Lamp 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.
Solchenbach, Sophie, et al.. (2024). Electrolyte motion induced salt inhomogeneity – a novel aging mechanism in large-format lithium-ion cells. Energy & Environmental Science. 17(19). 7294–7317. 26 indexed citations
2.
Adam, Alexander, et al.. (2024). Depletion of Electrolyte Salt Upon Calendaric Aging of Lithium-Ion Batteries and its Effect on Cell Performance. Journal of The Electrochemical Society. 171(6). 60506–60506. 32 indexed citations
3.
Shi, Jiayan, Chicheung Su, Rachid Amine, et al.. (2023). Prelithiation of Lithium Peroxide for Silicon Anode: Achieving a High Activation Rate. ACS Applied Materials & Interfaces. 15(22). 26710–26717. 11 indexed citations
4.
Kim, Un‐Hyuck, Geon‐Tae Park, Patrick Conlin, et al.. (2021). Cation ordered Ni-rich layered cathode for ultra-long battery life. Energy & Environmental Science. 14(3). 1573–1583. 141 indexed citations
5.
Muy, Sokseiha, Johannes Voss, Roman Schlem, et al.. (2019). High-Throughput Screening of Solid-State Li-Ion Conductors Using Lattice-Dynamics Descriptors. iScience. 16. 270–282. 203 indexed citations
6.
Muy, Sokseiha, John Christopher Bachman, Livia Giordano, et al.. (2018). Tuning mobility and stability of lithium ion conductors based on lattice dynamics. Energy & Environmental Science. 11(4). 850–859. 203 indexed citations
7.
Muy, Sokseiha, John Christopher Bachman, Hao-Hsun Chang, et al.. (2018). Lithium Conductivity and Meyer-Neldel Rule in Li3PO4–Li3VO4–Li4GeO4 Lithium Superionic Conductors. Chemistry of Materials. 30(16). 5573–5582. 80 indexed citations
8.
Gao, Han, Filippo Maglia, Peter Lamp, Khalil Amine, & Zonghai Chen. (2017). Mechanistic Study of Electrolyte Additives to Stabilize High-Voltage Cathode–Electrolyte Interface in Lithium-Ion Batteries. ACS Applied Materials & Interfaces. 9(51). 44542–44549. 73 indexed citations
9.
Gao, Han, Tianyuan Ma, Li Wang, et al.. (2017). Protecting Al foils for high-voltage lithium-ion chemistries. Materials Today Energy. 7. 18–26. 37 indexed citations
10.
Myung, Seung‐Taek, Filippo Maglia, Kang-Joon Park, et al.. (2016). Nickel-Rich Layered Cathode Materials for Automotive Lithium-Ion Batteries: Achievements and Perspectives. ACS Energy Letters. 2(1). 196–223. 1185 indexed citations breakdown →
11.
Yoon, Chong Seung, Jang‐Yeon Hwang, Sung Jin Kim, et al.. (2016). High-energy-density lithium-ion battery using a carbon-nanotube–Si composite anode and a compositionally graded Li[Ni0.85Co0.05Mn0.10]O2 cathode. Energy & Environmental Science. 9(6). 2152–2158. 281 indexed citations
12.
Zeng, Xiaoqiao, Gui‐Liang Xu, Yan Li, et al.. (2016). Kinetic Study of Parasitic Reactions in Lithium-Ion Batteries: A Case Study on LiNi0.6Mn0.2Co0.2O2. ACS Applied Materials & Interfaces. 8(5). 3446–3451. 93 indexed citations
13.
Gallagher, Kevin G., Stephen E. Trask, Christoph Bauer, et al.. (2015). Optimizing Areal Capacities through Understanding the Limitations of Lithium-Ion Electrodes. Journal of The Electrochemical Society. 163(2). A138–A149. 551 indexed citations breakdown →
14.
Melbert, Joachim, et al.. (2012). Cycle Life Investigations on Different Li-Ion Cell Chemistries for PHEV Applications Based on Real Life Conditions. SAE technical papers on CD-ROM/SAE technical paper series. 1. 6 indexed citations
15.
Lamp, Peter, et al.. (2003). Development of an Auxiliary Power Unit with Solid Oxide Fuel Cells for Automotive Applications. Fuel Cells. 3(3). 146–152. 65 indexed citations
16.
Lamp, Peter, Robert H. Eibl, & G. Buschhorn. (2002). Measurement of electron mobility in liquid and gaseous argon at low electric field strengths and in the critical region. ? 9. 39–45. 1 indexed citations
17.
Gaderer, Matthias, et al.. (2001). Processes and Economics for Energetic Use of Cotton Plant Residues. eCommons (Cornell University). 1 indexed citations
18.
Jörissen, Ludwig, et al.. (1998). Hydrogen storage in carbon materials—preliminary results. AIP conference proceedings. 481–484. 1 indexed citations
19.
Lamp, Peter & G. Buschhorn. (1994). Measurement of electron transport in liquid argon in crossed electric and magnetic fields. IEEE Transactions on Dielectrics and Electrical Insulation. 1(3). 407–411. 1 indexed citations
20.
Eibl, Robert H., Peter Lamp, & G. Buschhorn. (1990). Measurement of electron mobility in liquid and critical argon at low electric-field strengths. Physical review. B, Condensed matter. 42(7). 4356–4362. 10 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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