2026 Stefania Panero: Materials Science Researcher – H-Index, Publications & Awards

D-Index & Metrics

Discipline name	D-Index	World Ranking	Current World Ranking	National Ranking	Current National Ranking	Publications	Citations
Materials Science	66	5409	5232	77	74	260	14450
Chemistry	67	6962	6311	164	147	259	14857

Discipline name

D-Index

World Ranking

Current World Ranking

National Ranking

Current National Ranking

Publications

Citations

Materials Science

5409

5232

260

14450

Chemistry

6962

6311

164

147

259

14857

Materials Science

D-Index

Citations

14450

World Ranking

5409

National Ranking

Chemistry

D-Index

Citations

14857

World Ranking

6962

National Ranking

164

Overview

Stefania Panero is affiliated with Sapienza University of Rome in Italy. The primary focus of their research lies within the field of Engineering, with a particular emphasis on Electrical and Electronic Engineering and Automotive Engineering as subfields.

The scientist's work concentrates heavily on topics related to advanced energy storage and battery technologies. Specific themes include:

Advanced Battery Materials and Technologies
Advancements in Battery Materials
Advanced Battery Technologies Research
Fuel Cells and Related Materials
Advanced battery technologies research

Recent papers authored or co-authored by Stefania Panero include:

Sn/C composite anodes for bulk-type all-solid-state batteries, 2021, Electrochimica Acta
Silicon-Based Composite Anodes for All-Solid-State Lithium-Ion Batteries Conceived by a Mixture Design Approach, 2022, ChemSusChem
A Novel Li⁺-Conducting Polymer Membrane Gelled by Fluorine-Free Electrolyte Solutions for Li-Ion Batteries, 2020, Batteries & Supercaps

Stefania Panero has collaborated frequently with several researchers, including:

Maria Assunta Navarra
Akiko Tsurumaki
Giovanna Maresca
N. Suzuki
Yûichi Aihara

Their publications have appeared mainly in the following scientific venues:

ChemSusChem
Electrochimica Acta
Batteries & Supercaps

Best Publications

Nanostructured Sn–C Composite as an Advanced Anode Material in High‐Performance Lithium‐Ion Batteries

Gaelle Derrien;Jusef Hassoun;Stefania Panero;Bruno Scrosati

992
Citations
A laboratory-scale lithium-ion battery recycling process

M Contestabile;S Panero;B Scrosati

544
Citations
An Advanced Lithium-Ion Battery Based on a Graphene Anode and a Lithium Iron Phosphate Cathode

Jusef Hassoun;Francesco Bonaccorso;Marco Agostini;Marco Angelucci

538
Citations
High-rate, long-life Ni-Sn nanostructured electrodes for lithium-ion batteries

Jusef Hassoun;Stefania Panero;Patrice Simon;Pierre Louis Taberna

456
Citations
A Nanostructured Sn–C Composite Lithium Battery Electrode with Unique Stability and High Electrochemical Performance

Jusef Hassoun;Gaelle Derrien;Stefania Panero;Bruno Scrosati

456
Citations
A lithium-ion battery based on a graphene nanoflakes ink anode and a lithium iron phosphate cathode

Jusef Hassoun;Francesco Bonaccorso;Marco Agostini;Marco Angelucci

418
Citations
Progress in lithium polymer battery R&D

B. Scrosati;F. Croce;S. Panero

324
Citations
A New, Safe, High‐Rate and High‐Energy Polymer Lithium‐Ion Battery

Jusef Hassoun;Stefania Panero;Priscilla Reale;Bruno Scrosati

266
Citations
Electron transfer from a solid-state electrode assisted by methyl viologen sustains efficient microbial reductive dechlorination of TCE.

Federico Aulenta;Alessandro Catervi;Mauro Majone;Stefania Panero

252
Citations
Use of bench-top NMR to measure the density, composition and desorption isotherm of C–S–H in cement paste

Aca Muller;KL Scrivener;Agata Gajewicz;Peter McDonald

224
Citations
Electrodeposited Ni–Sn intermetallic electrodes for advanced lithium ion batteries

Jusef Hassoun;S. Panero;B. Scrosati

200
Citations
Mixtures of ionic liquid-Alkylcarbonates as electrolytes for safe lithium-ion batteries

L. Lombardo;S. Brutti;Navarra;S. Panero

199
Citations
High-Resolution In-Situ Structural Measurements of the Li4/3Ti5/3O4 “Zero-Strain” Insertion Material

F. Ronci;P. Reale;B. Scrosati;S. Panero

196
Citations
The role of conductive polymers in advanced electrochemical technology

F. Croce;S. Panero;S. Passerini;B. Scrosati

186
Citations
Solid solutions Li1+xV3O8 as cathodes for high rate secondary Li batteries

G. Pistoia;S. Panero;M. Tocci;R.V. Moshtev

178
Citations
Composite PEOn:NaTFSI polymer electrolyte: Preparation, thermal and electrochemical characterization

J. Serra Moreno;M. Armand;M.B. Berman;S.G. Greenbaum

177
Citations
Microbial reductive dechlorination of trichloroethene to ethene with electrodes serving as electron donors without the external addition of redox mediators

Federico Aulenta;Andrea Canosa;Priscilla Reale;Simona Rossetti

174
Citations
New types of Brönsted acid-base ionic liquids-based membranes for applications in PEMFCs.

Alessandra Fernicola;Stefania Panero;Bruno Scrosati;Masahiro Tamada

150
Citations
Trichloroethene dechlorination and H2 evolution are alternative biological pathways of electric charge utilization by a dechlorinating culture in a bioelectrochemical system

Federico Aulenta;Andrea Canosa;Mauro Majone;Stefania Panero

148
Citations
Rechargeable Li / Li1 + x V 3 O 8 Cells

S. Panero;M. Pasquali;G. Pistoia

147
Citations