Silicon-based anodes for lithium-ion batteries: Effectiveness of materials synthesis and electrode preparation

Casimir, Anix; Zhang, Hanguang; Ogoke, Ogechi; Amine, Joseph; Lü, Jun; Wu, Gang

doi:10.1016/j.nanoen.2016.07.023

Cited by 465 publications

(292 citation statements)

References 115 publications

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“…Silicon (Si) with the theoretical capacity of nearly 3580 mAh g −1 (Li 3.75 Si) is an ideal anode material to replace the traditional graphite anode with theoretical capacity of 372 mAh g −1 . However, the huge volume change (over 300%) during lithiation/delithiation possess causes severe pulverization, loss of electric conductivity, and continuously growing solid electrolyte interphase (SEI), thus resulting in rapid capacity fading …”

Section: Introductionmentioning

confidence: 99%

3D Network Binder via In Situ Cross‐Linking on Silicon Anodes with Improved Stability for Lithium‐Ion Batteries

Chen

Lin

et al. 2019

Macro Chemistry & Physics

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Silicon (Si) has attracted intensive academic and commercial attention due to its extremely high theoretical capacity. However, it is still far away from practical application because of its fast capacity fading, which is caused by the huge volume change. Here, a novel network polymer binder is synthesized through in situ thermal crosslinking of water‐soluble carboxymethyl cellulose (CMC) and maleic anhydride (MAH). The as‐obtained polymer binder network can effectively restrict the huge volume change of Si anodes upon lithiation. Because of the significantly enhanced structural stability, the Si anodes with network polymer binder deliver enhanced electrochemical performance, with a capacity of 996 mAh g−1 at a high current density of 1 A g−1 after 120 cycles under high mass loading. Most importantly, a high average Coulomb efficiency (CE) of 99.4% is obtained, which is superior over the average CE (98.7%) of Si only using CMC as binder. It is considered that this novel 3D network cross‐linking binder can be used for high‐capacity anode materials in next‐generation Li‐ion batteries.

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Section: Introductionmentioning

confidence: 99%

3D Network Binder via In Situ Cross‐Linking on Silicon Anodes with Improved Stability for Lithium‐Ion Batteries

Chen

Lin

et al. 2019

Macro Chemistry & Physics

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“…[21,22] So, optimum mechanical property is required for desirable battery performance. [22] In order to achieve appropriate battery-performance, optimum physical properties and high ionic conductivity should be considered. The ionic conductivity was measured by EIS varying temperature ranges from 20 to 80 °C (Figure 2d).…”

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confidence: 99%

High‐Performance Li–Se Battery Enabled via a One‐Piece Cathode Design

Kim

Cho

Lee

2019

Advanced Energy Materials

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conductivity, and high volumetric energy density. [8][9][10] Moreover, Se is a reasonably priced element, being around $ 32 per kg when purchased in industrial quantities. [4] Comparable to the S cathode, a Se cathode also has major concerns regarding volume expansion of Se (>97%) and shuttle effects by polyselenide intermediates. [11,12] To address these concerns, most studies have focused on the incorporation of functional materials such as porous carbons, conductive polymers, and metal oxides. [5][6][7] In general, the Se cathode is prepared by complicated multistep processes, which are consisted of encapsulating of Se into porous carbon (Se/C composite), slurry preparation using high energy ball-mixing of Se/C composites and other additives, deposition of the slurry on a current collector, and finally pressing the cathode. [11][12][13] In the Se cathode, there exist complex interfaces due to multicomponents system. Furthermore, all the additives do not contribute to electrochemical redox reaction lowering energy density and polymer binder even can increase interfacial resistance. Thus, it would be highly desirable to provide a simple fabrication process and stable cycling to Li-Se battery. [14][15][16] Herein, we introduced a new design of Se cathode, which was simply prepared by electrochemical deposition of Se on Nifoam and subsequent coating of a thin layer of solid polymer electrolyte (SPE). The electrodeposition of Se on Ni-foam is an easy process, and direct contacts of Se on current collector provide facile charge transport. The SPE was easily prepared via crosslinking reaction of poly(ethylene glycol) diglycidyl ether (DE-PEG) and diamino-poly(propylene oxide) (DA-PPG) with subsequent immersion in a LiPF 6 based carbonate electrolyte. The elastic SPE layer is able to protect the delamination problem of Se from the Ni-foam controlling the volume expansion of Se, to provide facile ionic pathway, and to suppress Li-dendrite growth. The designed "One-piece" Se cathode was produced by facile manufacturing process and exhibited an ultrastable cycling performance of 0.001% capacity degradation per cycle for 3000 cycles at 1 C rate.A schematic preparation of the one-piece Se cathode is shown in Figure 1. In the preparation of the one-piece Se cathode, Se was electrodeposited on the Ni-foam and a prepolymer solution of SPE was poured on the Se/Ni-foam to fill the pore. The prepolymer was thermally cross-linked and liquid electrolyte was impregnated. At the bottom of Ni-foam, a thin layer (≈20 µm) of SPE was formed which was directly contacted with Li metal foil. Moreover, the thickness of SPE in A high-performance Li-Se battery is demonstrated by adopting a novel Se cathode design. The Se cathode is a one-piece body combined with a Se deposited current collector and a solid polymer electrolyte (SPE). In the preparation of the Se cathode, Se is electrodeposited on Ni-foam, and the pores are filled with SPE layers. Through this electrodeposition, the cathode is easily fabricated, and charge transports are facile...

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“…The current gravimetric capacity (amount of lithium that can be stored per mass of anodic material) of graphite anodes is around 372 mAh g −1 . New anode materials such as lithium titanate (LiTi 5 O 12 ), carbon nanotubes or Al, Sn and Si compounds are being studied for use as alternative anodes . The aforementioned materials would increase the value of the waste of LIBs, involving a significant growth of the concern about recycling processes.…”

Section: A New Challenge For Edr: Lithium Ion Battery Recyclingmentioning

confidence: 99%

Electrodialytic processes in solid matrices. New insights into battery recycling. A review

Villén-Guzmán

Arhoun

Vereda‐Alonso

et al. 2019

J of Chemical Tech & Biotech

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Electrodialytic remediation has been widely applied to the recovery of different contaminants from numerous solid matrices, solving emerging issues of environmental concern. Results and conclusions reported in studies about real contaminated matrices are summarized in this work. The influence of pH value on the treatment effectiveness has been widely proved, highlighting the phenomenon of ‘water splitting’ in the membrane surface. This dissociation of water molecules is related to the ‘limiting current’ which it is desirable to exceed at the anion exchange membrane in order to produce the entering of protons toward the solid matrix. Other important parameters for the optimization of the technique, such as the current density and the liquid/solid ratio, are also discussed through the revision of studies using real solid matrices. This work also focuses on the pioneer proposal of electrokinetic technologies for the recycling of lithium ion batteries, considering the relevance of waste properties in the design and optimization of the technique. From a thorough literature revision, it could be concluded that further experimental results are needed to allow an optimal application of the technique to the rising problem of residues from batteries. The main aim of this work is to take the first steps in the recovery of valuable metals such as Li and Co from spent batteries, incorporating principles of green chemistry. © 2019 Society of Chemical Industry

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Silicon-based anodes for lithium-ion batteries: Effectiveness of materials synthesis and electrode preparation

Cited by 465 publications

References 115 publications

3D Network Binder via In Situ Cross‐Linking on Silicon Anodes with Improved Stability for Lithium‐Ion Batteries

3D Network Binder via In Situ Cross‐Linking on Silicon Anodes with Improved Stability for Lithium‐Ion Batteries

High‐Performance Li–Se Battery Enabled via a One‐Piece Cathode Design

Electrodialytic processes in solid matrices. New insights into battery recycling. A review

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