# | Title | Journal | Year | Citations |
---|
1 | A solid future for battery development | Nature Energy | 2016 | 2,319 |
2 | Semiconductor Composites: Strategies for Enhancing Charge Carrier Separation to Improve Photocatalytic Activity | Advanced Functional Materials | 2014 | 1,293 |
3 | Use of Graphite as a Highly Reversible Electrode with Superior Cycle Life for Sodium‐Ion Batteries by Making Use of Co‐Intercalation Phenomena | Angewandte Chemie - International Edition | 2014 | 730 |
4 | Capacity Fade in Solid-State Batteries: Interphase Formation and Chemomechanical Processes in Nickel-Rich Layered Oxide Cathodes and Lithium Thiophosphate Solid Electrolytes | Chemistry of Materials | 2017 | 655 |
5 | Chemo-mechanical expansion of lithium electrode materials – on the route to mechanically optimized all-solid-state batteries | Energy and Environmental Science | 2018 | 512 |
6 | Room-temperature sodium-ion batteries: Improving the rate capability of carbon anode materials by templating strategies | Energy and Environmental Science | 2011 | 491 |
7 | Anisotropic Lattice Strain and Mechanical Degradation of High- and Low-Nickel NCM Cathode Materials for Li-Ion Batteries | Journal of Physical Chemistry C | 2017 | 472 |
8 | Physicochemical Concepts of the Lithium Metal Anode in Solid-State Batteries | Chemical Reviews | 2020 | 468 |
9 | TEMPO: A Mobile Catalyst for Rechargeable Li-O2 Batteries | Journal of the American Chemical Society | 2014 | 466 |
10 | Toward a Fundamental Understanding of the Lithium Metal Anode in Solid-State Batteries—An Electrochemo-Mechanical Study on the Garnet-Type Solid Electrolyte Li6.25Al0.25La3Zr2O12 | ACS Applied Materials & Interfaces | 2019 | 461 |
11 | Influence of Lattice Polarizability on the Ionic Conductivity in the Lithium Superionic Argyrodites Li6PS5X (X = Cl, Br, I) | Journal of the American Chemical Society | 2017 | 446 |
12 | From lithium to sodium: cell chemistry of room temperature sodium–air and sodium–sulfur batteries | Beilstein Journal of Nanotechnology | 2015 | 368 |
13 | Dynamic formation of a solid-liquid electrolyte interphase and its consequences for hybrid-battery concepts | Nature Chemistry | 2016 | 340 |
14 | Inducing High Ionic Conductivity in the Lithium Superionic Argyrodites Li6+xP1–xGexS5I for All-Solid-State Batteries | Journal of the American Chemical Society | 2018 | 331 |
15 | Challenges in Lithium Metal Anodes for Solid-State Batteries | ACS Energy Letters | 2020 | 322 |
16 | Nanosizing and Nanoconfinement: New Strategies Towards Meeting Hydrogen Storage Goals | ChemSusChem | 2010 | 321 |
17 | Pseudocapacitive Contributions to Charge Storage in Highly Ordered Mesoporous Group V Transition Metal Oxides with Iso-Oriented Layered Nanocrystalline Domains | Journal of the American Chemical Society | 2010 | 320 |
18 | Conversion reactions for sodium-ion batteries | Physical Chemistry Chemical Physics | 2013 | 319 |
19 | Non-metal doping of transition metal oxides for visible-light photocatalysis | Catalysis Today | 2014 | 311 |
20 | Lithium-Metal Growth Kinetics on LLZO Garnet-Type Solid Electrolytes | Joule | 2019 | 292 |
21 | Visualization of the Interfacial Decomposition of Composite Cathodes in Argyrodite-Based All-Solid-State Batteries Using Time-of-Flight Secondary-Ion Mass Spectrometry | Chemistry of Materials | 2019 | 246 |
22 | Diffusion Limitation of Lithium Metal and Li–Mg Alloy Anodes on LLZO Type Solid Electrolytes as a Function of Temperature and Pressure | Advanced Energy Materials | 2019 | 240 |
23 | Polycrystalline and Single Crystalline NCM Cathode Materials—Quantifying Particle Cracking, Active Surface Area, and Lithium Diffusion | Advanced Energy Materials | 2021 | 237 |
24 | Between Scylla and Charybdis: Balancing Among Structural Stability and Energy Density of Layered NCM Cathode Materials for Advanced Lithium-Ion Batteries | Journal of Physical Chemistry C | 2017 | 233 |
25 | Lithium ion conductivity in Li2S–P2S5 glasses – building units and local structure evolution during the crystallization of superionic conductors Li3PS4, Li7P3S11 and Li4P2S7 | Journal of Materials Chemistry A | 2017 | 233 |
26 | Electrochemical stability of non-aqueous electrolytes for sodium-ion batteries and their compatibility with Na0.7CoO2 | Physical Chemistry Chemical Physics | 2014 | 217 |
27 | Recent progress in soft-templating of porous carbon materials | Soft Matter | 2012 | 213 |
28 | Systematical electrochemical study on the parasitic shuttle-effect in lithium-sulfur-cells at different temperatures and different rates | Journal of Power Sources | 2014 | 212 |
29 | Redox-active cathode interphases in solid-state batteries | Journal of Materials Chemistry A | 2017 | 206 |
30 | Metal–organic framework nanofibers viaelectrospinning | Chemical Communications | 2011 | 203 |
31 | Exceptional Photocatalytic Activity of Ordered Mesoporous β-Bi2O3 Thin Films and Electrospun Nanofiber Mats | Chemistry of Materials | 2010 | 197 |
32 | Graphite as Cointercalation Electrode for Sodium‐Ion Batteries: Electrode Dynamics and the Missing Solid Electrolyte Interphase (SEI) | Advanced Energy Materials | 2018 | 191 |
33 | Hierarchically Porous Monolithic LiFePO4/Carbon Composite Electrode Materials for High Power Lithium Ion Batteries | Chemistry of Materials | 2009 | 189 |
34 | Ordered Mesoporous Sb-, Nb-, and Ta-Doped SnO2 Thin Films with Adjustable Doping Levels and High Electrical Conductivity | ACS Nano | 2009 | 175 |
35 | Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries | Advanced Materials | 2020 | 173 |
36 | A comparative study on the impact of different glymes and their derivatives as electrolyte solvents for graphite co-intercalation electrodes in lithium-ion and sodium-ion batteries | Physical Chemistry Chemical Physics | 2016 | 172 |
37 | Ordered Large-Pore Mesoporous Li4Ti5O12 Spinel Thin Film Electrodes with Nanocrystalline Framework for High Rate Rechargeable Lithium Batteries: Relationships among Charge Storage, Electrical Conductivity, and Nanoscale Structure | Chemistry of Materials | 2011 | 171 |
38 | A chemically driven insulator–metal transition in non-stoichiometric and amorphous gallium oxide | Nature Materials | 2008 | 166 |
39 | Colloidal Crystal Templating to Produce Hierarchically Porous LiFePO4 Electrode Materials for High Power Lithium Ion Batteries | Chemistry of Materials | 2009 | 163 |
40 | The impact of carbon materials on the hydrogen storage properties of light metal hydrides | Journal of Materials Chemistry | 2011 | 156 |
41 | How To Improve Capacity and Cycling Stability for Next Generation Li–O2 Batteries: Approach with a Solid Electrolyte and Elevated Redox Mediator Concentrations | ACS Applied Materials & Interfaces | 2016 | 151 |
42 | Materials design of ionic conductors for solid state batteries | Progress in Energy | 2020 | 146 |
43 | Ionic liquids as green electrolytes for the electrodeposition of nanomaterials | Green Chemistry | 2007 | 143 |
44 | In Situ Monitoring of Fast Li-Ion Conductor Li7P3S11 Crystallization Inside a Hot-Press Setup | Chemistry of Materials | 2016 | 138 |
45 | Experimental Assessment of the Practical Oxidative Stability of Lithium Thiophosphate Solid Electrolytes | Chemistry of Materials | 2019 | 138 |
46 | Benchmarking Anode Concepts: The Future of Electrically Rechargeable Zinc–Air Batteries | ACS Energy Letters | 2019 | 136 |
47 | Influence of the Fe:Ni Ratio and Reaction Temperature on the Efficiency of (FexNi1–x)9S8 Electrocatalysts Applied in the Hydrogen Evolution Reaction | ACS Catalysis | 2018 | 134 |
48 | Influence of NCM Particle Cracking on Kinetics of Lithium-Ion Batteries with Liquid or Solid Electrolyte | Journal of the Electrochemical Society | 2020 | 134 |
49 | Designing Ionic Conductors: The Interplay between Structural Phenomena and Interfaces in Thiophosphate-Based Solid-State Batteries | Chemistry of Materials | 2018 | 131 |
50 | Copper sulfides for rechargeable lithium batteries: Linking cycling stability to electrolyte composition | Journal of Power Sources | 2014 | 130 |