| 1 - 7 |
Carbon nanofibers with highly dispersed tin and tin antimonide nanoparticles: Preparation via electrospinning and application as the anode materials for lithium-ion batteries
Li Z, Zhang JW, Shu J, Chen JP, Gong CH, Guo JH, Yu LG, Zhang JW |
| 8 - 17 |
Corset-like solid electrolyte interface for fast charging of silicon wire anodes
Hansen S, Shree S, Neubuser G, Carstensen J, Kienle L, Adelung R |
| 18 - 25 |
Rich-burn, flame-assisted fuel cell, quick-mix, lean-burn (RFQL) combustor and power generation
Milcarek RJ, Ahn J |
| 26 - 29 |
Mechanism of chromium poisoning the conventional cathode material for solid oxide fuel cells
Zhang XQ, Yu GS, Zeng SM, Parbey J, Xiao SH, Li BH, Li TS, Andersson M |
| 30 - 37 |
Power ramp rate capabilities of a 5 kW proton exchange membrane fuel cell system with discrete ejector control
Nikiforow K, Pennanen J, Ihonen J, Uski S, Koski P |
| 38 - 45 |
Capacity extended bismuth-antimony cathode for high-performance liquid metal battery
Dai T, Zhao Y, Ning XH, Narayan RL, Li J, Shan ZW |
| 46 - 55 |
X-ray computed tomography comparison of individual and parallel assembled commercial lithium iron phosphate batteries at end of life after high rate cycling
Carter R, Huhman B, Love CT, Zenyuk IV |
| 56 - 65 |
Fast charge implications: Pack and cell analysis and comparison
Tanim TR, Shirk MG, Bewley RL, Dufek EJ, Liaw BY |
| 66 - 71 |
Carbon-shell-constrained silicon cluster derived from Al-Si alloy as long-cycling life lithium ion batteries anode
Su JM, Zhang CC, Chen X, Liu SY, Huang T, Yu AS |
| 72 - 83 |
4D imaging of polymer electrolyte membrane fuel cell catalyst layers by soft X-ray spectro-tomography
Wu J, Melo LGA, Zhu XH, West MM, Berejnov V, Susac D, Stumper J, Hitchcock AP |
| 84 - 93 |
Statistical analysis of the effect of temperature and inlet humidities on the parameters of a semiempirical model of the internal resistance of a polymer electrolyte membrane fuel cell
Giner-Sanz JJ, Ortega EM, Perez-Herranz V |
| 94 - 100 |
Investigation of low-cost oligoanthraquinones for alkaline, aqueous rechargeable batteries with cell potential up to 1.13 V
Drazevic E, Andersen AS, Wedege K, Henriksen ML, Hinge M, Bentien A |
| 101 - 106 |
Solid oxide fuel cells with apatite-type lanthanum silicate based electrolyte films deposited by radio frequency magnetron sputtering
Liu YX, Wang SF, Hsu YF, Wang CH |
| 107 - 115 |
High-temperature solid electrolyte interphases (SEI) in graphite electrodes
Rodrigues MTF, Sayed FN, Gullapalli H, Ajayan PM |
| 116 - 126 |
Nano-micro carbon spheres anchored on porous carbon derived from dual-biomass as high rate performance supercapacitor electrodes
Liu SB, Zhao Y, Zhang BH, Xia H, Zhou JF, Xie WK, Li HJ |
| 127 - 135 |
Lead paste recycling based on conversion into battery grade oxides. Electrochemical tests and industrial production of new batteries
Fusillo G, Rosestolato D, Scura F, Cattarin S, Mattarozzi L, Guerriero P, Gambirasi A, Brianese N, Staiti P, Guerriero R, La Sala G |
| 136 - 155 |
Electrolyte bi-layering strategy to improve the performance of an intermediate temperature solid oxide fuel cell: A review
Prakash BS, Pavitra R, Kumar SS, Aruna ST |
| 156 - 163 |
Polyaniline-encapsulated silicon on three-dimensional carbon nanotubes foam with enhanced electrochemical performance for lithium-ion batteries
Zhou XM, Liu Y, Du CY, Ren Y, Mu TS, Zuo PJ, Yin GP, Ma YL, Cheng XQ, Gao YZ |
| 164 - 170 |
Ethylene carbonate-free fluoroethylene carbonate-based electrolyte works better for freestanding Si-based composite paper anodes for Li-ion batteries
Yao K, Zheng JP, Liang R |
| 171 - 180 |
Design of high-performance cathode materials with single-phase pathway for sodium ion batteries: A study on P2-Na-x(LiyMn1-y)O-2 compounds
Yang LF, Li X, Ma XT, Xiong S, Liu P, Tang YZ, Cheng S, Hu YY, Liu ML, Chen HL |
| 181 - 189 |
In situ X-ray micro-CT characterization of chemo-mechanical relaxations during Sn lithiation
Gonzalez JF, Antartis DA, Chasiotis I, Dillon SJ, Lambros J |
