| # | Title | Journal | Year | Citations |
|---|
| 1 | The role of graphene for electrochemical energy storage | Nature Materials | 2015 | 2,237 |
| 2 | Ultrathin, highly flexible and stretchable PLEDs | Nature Photonics | 2013 | 832 |
| 3 | Lithium ion, lithium metal, and alternative rechargeable battery technologies: the odyssey for high energy density | Journal of Solid State Electrochemistry | 2017 | 787 |
| 4 | Electrochemical in situ investigations of SEI and dendrite formation on the lithium metal anode | Physical Chemistry Chemical Physics | 2015 | 621 |
| 5 | Post-lithium-ion battery cell production and its compatibility with lithium-ion cell production infrastructure | Nature Energy | 2021 | 612 |
| 6 | A rechargeable zinc-air battery based on zinc peroxide chemistry | Science | 2021 | 551 |
| 7 | The mechanism of HF formation in LiPF6 based organic carbonate electrolytes | Electrochemistry Communications | 2012 | 401 |
| 8 | Current research trends and prospects among the various materials and designs used in lithium-based batteries | Journal of Applied Electrochemistry | 2013 | 362 |
| 9 | Mechanical Surface Modification of Lithium Metal: Towards Improved Li Metal Anode Performance by Directed Li Plating | Advanced Functional Materials | 2015 | 343 |
| 10 | Dual-graphite cells based on the reversible intercalation of bis(trifluoromethanesulfonyl)imide anions from an ionic liquid electrolyte | Energy and Environmental Science | 2014 | 335 |
| 11 | Best Practice: Performance and Cost Evaluation of Lithium Ion Battery Active Materials with Special Emphasis on Energy Efficiency | Chemistry of Materials | 2016 | 317 |
| 12 | Perspective on Performance, Cost, and Technical Challenges for Practical Dual-Ion Batteries | Joule | 2018 | 312 |
| 13 | Chemical and physical surface and bulk material characterization of white ProRoot MTA and two Portland cements | Dental Materials | 2005 | 287 |
| 14 | Reversible Intercalation of Bis(trifluoromethanesulfonyl)imide Anions from an Ionic Liquid Electrolyte into Graphite for High Performance Dual-Ion Cells | Journal of the Electrochemical Society | 2012 | 274 |
| 15 | Copper-coordinated cellulose ion conductors for solid-state batteries | Nature | 2021 | 262 |
| 16 | Pre-Lithiation Strategies for Rechargeable Energy Storage Technologies: Concepts, Promises and Challenges | Batteries | 2018 | 251 |
| 17 | Chemical analysis and bonding reaction of RelyX Unicem and Bifix composites—A comparative study | Dental Materials | 2006 | 233 |
| 18 | Nanoscale organization in piperidinium-based room temperature ionic liquids | Journal of Chemical Physics | 2009 | 221 |
| 19 | X-ray diffraction studies of the electrochemical intercalation of bis(trifluoromethanesulfonyl)imide anions into graphite for dual-ion cells | Journal of Power Sources | 2013 | 197 |
| 20 | Structural Changes in Li2MnO3 Cathode Material for Li‐Ion Batteries | Advanced Energy Materials | 2014 | 194 |
| 21 | Ultra-high cycling stability of poly(vinylphenothiazine) as a battery cathode material resulting from π–π interactions | Energy and Environmental Science | 2017 | 194 |
| 22 | A reality check and tutorial on electrochemical characterization of battery cell materials: How to choose the appropriate cell setup | Materials Today | 2020 | 193 |
| 23 | Toward Na-ion Batteries—Synthesis and Characterization of a Novel High Capacity Na Ion Intercalation Material | Chemistry of Materials | 2013 | 192 |
| 24 | The influence of different conducting salts on the metal dissolution and capacity fading of NCM cathode material | Electrochimica Acta | 2014 | 188 |
| 25 | Synthesis and electrochemical performance of the high voltage cathode material Li[Li0.2Mn0.56Ni0.16Co0.08]O2 with improved rate capability | Journal of Power Sources | 2011 | 181 |
| 26 | Use of natural binders and ionic liquid electrolytes for greener and safer lithium-ion batteries | Journal of Power Sources | 2011 | 180 |
| 27 | A Step toward High-Energy Silicon-Based Thin Film Lithium Ion Batteries | ACS Nano | 2017 | 178 |
| 28 | Surface Modification of Ni-Rich LiNi0.8Co0.1Mn0.1O2 Cathode Material by Tungsten Oxide Coating for Improved Electrochemical Performance in Lithium-Ion Batteries | ACS Applied Materials & Interfaces | 2019 | 177 |
| 29 | Hydration and internal properties of polyelectrolyte multilayers | Colloids and Surfaces A: Physicochemical and Engineering Aspects | 2007 | 174 |
| 30 | Energy barriers and activated dynamics in a supercooled Lennard-Jones liquid | Physical Review E | 2003 | 173 |
| 31 | Carbons from biomass precursors as anode materials for lithium ion batteries: New insights into carbonization and graphitization behavior and into their correlation to electrochemical performance | Carbon | 2018 | 168 |
| 32 | Running out of lithium? A route to differentiate between capacity losses and active lithium losses in lithium-ion batteries | Physical Chemistry Chemical Physics | 2017 | 162 |
| 33 | Graphite Recycling from Spent Lithium‐Ion Batteries | ChemSusChem | 2016 | 160 |
| 34 | Water sensitivity of layered P2/P3-NaxNi0.22Co0.11Mn0.66O2 cathode material | Journal of Materials Chemistry A | 2014 | 159 |
| 35 | A Mechanically Robust and Highly Ion‐Conductive Polymer‐Blend Coating for High‐Power and Long‐Life Lithium‐Ion Battery Anodes | Advanced Materials | 2015 | 159 |
| 36 | UV cross-linked, lithium-conducting ternary polymer electrolytes containing ionic liquids | Journal of Power Sources | 2010 | 157 |
| 37 | Nanocarbon Composites and Hybrids in Sustainability: A Review | ChemSusChem | 2012 | 157 |
| 38 | Hopping in a supercooled Lennard-Jones liquid: Metabasins, waiting time distribution, and diffusion | Physical Review E | 2003 | 156 |
| 39 | Does Size really Matter? New Insights into the Intercalation Behavior of Anions into a Graphite-Based Positive Electrode for Dual-Ion Batteries | Electrochimica Acta | 2016 | 156 |
| 40 | Influence of graphite surface modifications on the ratio of basal plane to “non-basal plane” surface area and on the anode performance in lithium ion batteries | Journal of Power Sources | 2012 | 147 |
| 41 | Mechanism of Anodic Dissolution of the Aluminum Current Collector in 1 M LiTFSI EC:DEC 3:7 in Rechargeable Lithium Batteries | Journal of the Electrochemical Society | 2013 | 143 |
| 42 | How Do Reactions at the Anode/Electrolyte Interface Determine the Cathode Performance in Lithium-Ion Batteries? | Journal of the Electrochemical Society | 2013 | 143 |
| 43 | A Tutorial into Practical Capacity and Mass Balancing of Lithium Ion Batteries | Journal of the Electrochemical Society | 2017 | 143 |
| 44 | Lithium‐Metal Foil Surface Modification: An Effective Method to Improve the Cycling Performance of Lithium‐Metal Batteries | Advanced Materials Interfaces | 2017 | 142 |
| 45 | Investigation of PF6− and TFSI− anion intercalation into graphitized carbon blacks and its influence on high voltage lithium ion batteries | Physical Chemistry Chemical Physics | 2014 | 138 |
| 46 | Three-Component, Interrupted Radical Heck/Allylic Substitution Cascade Involving Unactivated Alkyl Bromides | Journal of the American Chemical Society | 2020 | 135 |
| 47 | Molecular Environment and Enhanced Diffusivity of Li+ Ions in Lithium-Salt-Doped Ionic Liquid Electrolytes | Journal of Physical Chemistry Letters | 2011 | 134 |
| 48 | High silica zeolites with three-dimensional systems of large pore channels | Microporous and Mesoporous Materials | 2001 | 133 |
| 49 | Towards high-performance dual-graphite batteries using highly concentrated organic electrolytes | Electrochimica Acta | 2018 | 133 |
| 50 | Negative effective Li transference numbers in Li salt/ionic liquid mixtures: does Li drift in the “Wrong” direction? | Physical Chemistry Chemical Physics | 2018 | 128 |
