Single‐Phase Cu<sub>3</sub>SnS<sub>4</sub> Nanoparticles for Robust High Capacity Lithium‐Ion Battery Anodes

Sharma, Neha; Phase, D. M.; Thotiyl, Musthafa Ottakam; Ogale, Satishchandra

doi:10.1002/celc.201801772

Cited by 17 publications

(7 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the Nyquist plots of the Cu 2 SnS 3 electrodes at OCV (Fig. 7 a,b), a semicircle in the high-frequency region is attributed to the charge transfer resistance R ct and a straight sloping line in the low-frequency region is ascribed to Li + diffusion process in the bulk Zw [ 18 , 49 ]. The R ct of the annealed Cu 2 SnS 3 electrode is less than that of the as-prepared electrode.…”

Section: Resultsmentioning

confidence: 99%

Effects of Annealing on Electrochemical Properties of Solvothermally Synthesized Cu2SnS3 Anode Nanomaterials

et al. 2021

View full text Add to dashboard Cite

Cu2SnS3, as a modified material for high-capacity tin-based anodes, has great potential for lithium-ion battery applications. The solvothermal method is simple, convenient, cost-effective, and easy to scale up, and has thus been widely used for the preparation of nanocrystals. In this work, Cu2SnS3 nanoparticles were prepared by the solvothermal method. The effects of high-temperature annealing on the morphology, crystal structure, and electrochemical performance of a Cu2SnS3 nano-anode were studied. The experimental results indicate that high-temperature annealing improves the electrochemical performance of Cu2SnS3, resulting in higher initial coulombic efficiency and improved cycling and rate characteristics compared with those of the as-prepared sample.

show abstract

Section: Resultsmentioning

confidence: 99%

Effects of Annealing on Electrochemical Properties of Solvothermally Synthesized Cu2SnS3 Anode Nanomaterials

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Sharma et al synthesized this stoichiometric nanomaterial via one-pot solution processing method and tested the same for Liion battery anode (Figure 3a−c). 35 It delivered a high specific capacity of 1082 mAh g −1 at an applied current density of 0.2 A g −1 with an impressive cyclic stability of up to 950 cycles (Figure 3d,f). A specific capacity of 440 mAh g −1 at 3 A g −1 revealed that the system is capable of delivering high power (Figure 3e).…”

Section: Sulfides As Anode Materials For Li-ion Batterymentioning

confidence: 98%

Search for New Anode Materials for High Performance Li-Ion Batteries

Roy

Banerjee

Ogale

2022

ACS Appl. Mater. Interfaces

Self Cite

View full text Add to dashboard Cite

Owing to an unmatched combination of power and energy density along with cyclic stability, the Li-ion battery has qualified itself to be the highest performing rechargeable battery. Taking both transportable and stationary energy storage requirements into consideration, Li-ion batteries indeed stand tall in comparison to any other existing rechargeable battery technologies. However, graphite, which is still one of the best performing Li-ion anodes, has specific drawbacks in fulfilling the ever-increasing energy and power density requirements of the modern world. Therefore, further research on alternative anode materials is absolutely essential. Equally important is the search for and enhanced use of right earth abundant materials for battery electrodes so as to bring down the costs of the battery systems. In this spotlight article, we discuss the current research progress in the area of alternative anode materials for Li-ion battery, putting our own research work over the past several years into perspective. Starting from conversion anode systems like oxides and sulfides, to insertion cum alloying systems like transition metal carbides, to molecularly engineered open framework systems like metal organic frameworks (MOFs), covalent organic frameworks (COFs), and organic–inorganic hybrid perovskites (OIHPs), this spotlight provides a complete essence of the recent developments in the area of alternative anodes. The possible and potential impact of these new anode materials is detailed and discussed here.

show abstract

“…It has been understood that the kinetic limitations posed by the initial conversion process have been the roadblocks to establishing the status of conversion-cum-alloying materials as an advancement over the simple alloying materials (Sn and Sb) from a commercial standpoint. , The extensively researched strategy employing the addition of conducting support though successful in enhancing the kinetics leads to a decline in the overall achievable capacity because of the overall inactivity or small contribution of conducting support toward Na + uptake. ,− Doping by some transition metals, Cu, Co, and Ni has been employed with only a little success for similar reasons. ,− …”

Section: Introductionmentioning

confidence: 99%

“…The advancement has been attributed to the buffering effect offered by the matrix of Na-chalcogenide/pnictide generated after the conversion process. , The past decade has witnessed an increased effort toward improving the electrochemical performance of Sn and Sb-based conversion-cum-alloying materials, via structural modifications, morphological modifications, or compositing strategies. Notably, structural modifications have involved self-assembly (1D van der Waals Sb 2 S 3 ), phase transitions (hexagonal-SnS 2 to orthorhombic-SnS), and metal doping (Cu 4 SnS 4 ; Sn 5 SbP 3 ). , Morphological modifications have encompassed thin sheets (ultrathin layered SnSe nanoplates; ultralong Sb 2 Se 3 nanowires) , and 3D morphologies (SnS bundles; SnS 3D flowers). , Compositing strategies have focused on compositing with modified carbon forms (in situ growth of Sb 2 S 3 on multiwalled carbon nanotubes; Sb 2 Se 3 nanodots in carbon-confined nanofibers; SnS confined in carbon nanospheres; Sb 2 Se 3 wrapped in reduced graphene oxide) − and with structurally robust templating and supporting materials (core–shell–shell Sb 2 S 3 /Sb@TiO 2 nanorods) …”

Section: Introductionmentioning

confidence: 99%

“…Notably, structural modifications have involved self-assembly (1D van der Waals Sb 2 S 3 ), 22 phase transitions (hexagonal-SnS 2 to orthorhombic-SnS), 23 and metal doping (Cu 4 SnS 4 ; Sn 5 SbP 3 ). 24,25 thin sheets (ultrathin layered SnSe nanoplates; ultralong Sb 2 Se 3 nanowires) 26,27 and 3D morphologies (SnS bundles; SnS 3D flowers). 28,29 Compositing strategies have focused on compositing with modified carbon forms (in situ growth of Sb 2 S 3 on multiwalled carbon nanotubes; Sb 2 Se 3 nanodots in carbon-confined nanofibers; SnS confined in carbon nanospheres; Sb 2 Se 3 wrapped in reduced graphene oxide) 30−33 and with structurally robust templating and supporting materials (core−shell−shell Sb 2 S 3 /Sb@TiO 2 nanorods).…”

Section: ■ Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Sn-Doping in a Sb₂Se₃ Conversion-cum-Alloying Material Renders Efficient Sodium-Ion Electrochemical Performance: Facile Kinetics Achieved by Active Metal Doping

Islam

Majid

Wahid

2022

ACS Appl. Energy Mater.

View full text Add to dashboard Cite

Conversion-cum-alloying anode materials have particularly been sought after as promising high-capacity Na + anode materials owing to a double redox alkali-ion uptake offered by them. The addition of electrochemically nonactive conducting additives to enhance the sluggish kinetics of the conversion/deconversion step although instrumental in enhancing the kinetics ends up in a considerable decline in electrochemical capacity. Herein, we demonstrate an alternative strategy of doping an ultra-active Sn element in the well-known conversion-cum-alloying Na + battery anode, Sb 2 Se 3 . The Sn-doped Sb 2 Se 3 phase, Sn 0.2 Sb 1.8 Se 3 , besides depicting an enhanced capacity (reversible capacity of 520 mA h g −1 ) and cyclic stability, delivered an excellently improved rate performance (360 mA h g −1 at a current of 500 mA g −1 ) in comparison to pristine Sb 2 Se 3 which delivers a capacity of 45 mA h g −1 at the same current density. Electrochemical techniques such as cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) lend support to improved kinetics of the conversion/ deconversion process. The enhanced kinetics reflects in larger anodic peak currents (147 mA g −1 for Sn 0.2 Sb 1.8 Se 3 against 32 mA g −1 for Sb 2 Se 3 ) in CV plots and reduced charge-transfer resistance (R CT of 350 Ω for Sn 0.2 Sb 1.8 Se 3 against 670 Ω for Sb 2 Se 3 ) in EIS measurements. The electrochemical galvanostatic intermittent titration technique reveals a 3-order-magnitude increase in the diffusion coefficients (2.02 × 10 −14 −6.6 × 10 −11 cm 2 s −1 ) in the Sn 0.2 Sb 1.8 Se 3 in comparison to pristine Sb 2 Se 3 (2.5 × 10 −17 −4.2 × 10 −14 cm 2 s −1 ).

show abstract

Single‐Phase Cu₃SnS₄ Nanoparticles for Robust High Capacity Lithium‐Ion Battery Anodes

Cited by 17 publications

References 42 publications

Effects of Annealing on Electrochemical Properties of Solvothermally Synthesized Cu2SnS3 Anode Nanomaterials

Effects of Annealing on Electrochemical Properties of Solvothermally Synthesized Cu2SnS3 Anode Nanomaterials

Search for New Anode Materials for High Performance Li-Ion Batteries

Sn-Doping in a Sb₂Se₃ Conversion-cum-Alloying Material Renders Efficient Sodium-Ion Electrochemical Performance: Facile Kinetics Achieved by Active Metal Doping

Contact Info

Product

Resources

About

Single‐Phase Cu3SnS4 Nanoparticles for Robust High Capacity Lithium‐Ion Battery Anodes

Cited by 17 publications

References 42 publications

Effects of Annealing on Electrochemical Properties of Solvothermally Synthesized Cu2SnS3 Anode Nanomaterials

Effects of Annealing on Electrochemical Properties of Solvothermally Synthesized Cu2SnS3 Anode Nanomaterials

Search for New Anode Materials for High Performance Li-Ion Batteries

Sn-Doping in a Sb2Se3 Conversion-cum-Alloying Material Renders Efficient Sodium-Ion Electrochemical Performance: Facile Kinetics Achieved by Active Metal Doping

Contact Info

Product

Resources

About

Single‐Phase Cu₃SnS₄ Nanoparticles for Robust High Capacity Lithium‐Ion Battery Anodes

Sn-Doping in a Sb₂Se₃ Conversion-cum-Alloying Material Renders Efficient Sodium-Ion Electrochemical Performance: Facile Kinetics Achieved by Active Metal Doping