Review




Structured Review

Celgard LLC hcl/celgard tm 2400 monolayer membrane
Hcl/Celgard Tm 2400 Monolayer Membrane, supplied by Celgard LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/tm+2400+membrane/pmc10486141-188-17-19?v=Celgard+LLC
Average 90 stars, based on 1 article reviews
hcl/celgard tm 2400 monolayer membrane - by Bioz Stars, 2026-07
90/100 stars

Images



Similar Products

90
Celgard LLC hcl/celgard tm 2400 monolayer membrane
Hcl/Celgard Tm 2400 Monolayer Membrane, supplied by Celgard LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/tm+2400+membrane/pmc10486141-188-17-19?v=Celgard+LLC
Average 90 stars, based on 1 article reviews
hcl/celgard tm 2400 monolayer membrane - by Bioz Stars, 2026-07
90/100 stars
  Buy from Supplier

90
Celgard LLC tm 2400 membrane
A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.
Tm 2400 Membrane, supplied by Celgard LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/tm+2400+membrane/pmc08755825-103-26-25?v=Celgard+LLC
Average 90 stars, based on 1 article reviews
tm 2400 membrane - by Bioz Stars, 2026-07
90/100 stars
  Buy from Supplier

90
Celgard LLC tm 2400 membranes
A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.
Tm 2400 Membranes, supplied by Celgard LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/tm+2400+membrane/pmc08755825-146-50-49?v=Celgard+LLC
Average 90 stars, based on 1 article reviews
tm 2400 membranes - by Bioz Stars, 2026-07
90/100 stars
  Buy from Supplier

90
Celgard LLC membrane celgard tm 2400
A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.
Membrane Celgard Tm 2400, supplied by Celgard LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/tm+2400+membrane/pmc08755825-102-12-11?v=Celgard+LLC
Average 90 stars, based on 1 article reviews
membrane celgard tm 2400 - by Bioz Stars, 2026-07
90/100 stars
  Buy from Supplier

Image Search Results


A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.

Article Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles.

Techniques:

XPS survey ( A ); Raman scattering spectra ( B ); SEM image, EDAX spectra, and the corresponding N and S element mapping images ( C ) for the np-ANF before and after adsorption test Li 2 S 4 solution followed by rinsing with DOL/DME solution and drying in a glovebox. D Diffusion of LPS in H-type cell through Celgard TM 2400 and np-ANF membrane.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: XPS survey ( A ); Raman scattering spectra ( B ); SEM image, EDAX spectra, and the corresponding N and S element mapping images ( C ) for the np-ANF before and after adsorption test Li 2 S 4 solution followed by rinsing with DOL/DME solution and drying in a glovebox. D Diffusion of LPS in H-type cell through Celgard TM 2400 and np-ANF membrane.

Article Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles.

Techniques: Adsorption, Diffusion-based Assay

A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles. F The decay per cycle of Li–S batteries with various membrane Table ); G Cycling performance of Li–S batteries at 0.1C at various sulfur loading. H Cycling performance Li–S batteries with np-ANF membrane at a rate of 0.2C after 500 cycles at sulfur loading of 5.8 mg cm −2 .

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles. F The decay per cycle of Li–S batteries with various membrane Table ); G Cycling performance of Li–S batteries at 0.1C at various sulfur loading. H Cycling performance Li–S batteries with np-ANF membrane at a rate of 0.2C after 500 cycles at sulfur loading of 5.8 mg cm −2 .

Article Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles.

Techniques:

A Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400. B Cycling performance of Li–S batteries at 0.1C at 80 °C. C The capacity comparison of np-ANF and Celgard TM 2400 membrane at different temperatures. D Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C after 500 cycles at 80 °C.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400. B Cycling performance of Li–S batteries at 0.1C at 80 °C. C The capacity comparison of np-ANF and Celgard TM 2400 membrane at different temperatures. D Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C after 500 cycles at 80 °C.

Article Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles.

Techniques:

SEM images of the lithium electrode with np-ANF membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1) at a current density D 1 mA cm −2 and E 3 mA cm −2 . SEM images of the lithium electrode with Celgard TM 2400 membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1 at a current density ( F ), magnified image ( G ) 1 mA cm −2 and ( H ), and magnified image ( I ) 3 mA cm −2 .

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: SEM images of the lithium electrode with np-ANF membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1) at a current density D 1 mA cm −2 and E 3 mA cm −2 . SEM images of the lithium electrode with Celgard TM 2400 membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1 at a current density ( F ), magnified image ( G ) 1 mA cm −2 and ( H ), and magnified image ( I ) 3 mA cm −2 .

Article Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles.

Techniques: Stripping Membranes

A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.

Article Snippet: When the current density increased stepwise, the discharge capacities of the np-ANF were 1249, 1140, 1032, 916, and 801 mA hg −1 at 0.2C, 0.5C, 1C, 2C, and 3C, respectively, with a capacity retention of around 60%, exhibiting a much better high-temperature rate performance than that of cell with Celgard TM 2400 membranes.

Techniques:

XPS survey ( A ); Raman scattering spectra ( B ); SEM image, EDAX spectra, and the corresponding N and S element mapping images ( C ) for the np-ANF before and after adsorption test Li 2 S 4 solution followed by rinsing with DOL/DME solution and drying in a glovebox. D Diffusion of LPS in H-type cell through Celgard TM 2400 and np-ANF membrane.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: XPS survey ( A ); Raman scattering spectra ( B ); SEM image, EDAX spectra, and the corresponding N and S element mapping images ( C ) for the np-ANF before and after adsorption test Li 2 S 4 solution followed by rinsing with DOL/DME solution and drying in a glovebox. D Diffusion of LPS in H-type cell through Celgard TM 2400 and np-ANF membrane.

Article Snippet: When the current density increased stepwise, the discharge capacities of the np-ANF were 1249, 1140, 1032, 916, and 801 mA hg −1 at 0.2C, 0.5C, 1C, 2C, and 3C, respectively, with a capacity retention of around 60%, exhibiting a much better high-temperature rate performance than that of cell with Celgard TM 2400 membranes.

Techniques: Adsorption, Diffusion-based Assay

A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles. F The decay per cycle of Li–S batteries with various membrane Table ); G Cycling performance of Li–S batteries at 0.1C at various sulfur loading. H Cycling performance Li–S batteries with np-ANF membrane at a rate of 0.2C after 500 cycles at sulfur loading of 5.8 mg cm −2 .

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles. F The decay per cycle of Li–S batteries with various membrane Table ); G Cycling performance of Li–S batteries at 0.1C at various sulfur loading. H Cycling performance Li–S batteries with np-ANF membrane at a rate of 0.2C after 500 cycles at sulfur loading of 5.8 mg cm −2 .

Article Snippet: When the current density increased stepwise, the discharge capacities of the np-ANF were 1249, 1140, 1032, 916, and 801 mA hg −1 at 0.2C, 0.5C, 1C, 2C, and 3C, respectively, with a capacity retention of around 60%, exhibiting a much better high-temperature rate performance than that of cell with Celgard TM 2400 membranes.

Techniques:

A Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400. B Cycling performance of Li–S batteries at 0.1C at 80 °C. C The capacity comparison of np-ANF and Celgard TM 2400 membrane at different temperatures. D Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C after 500 cycles at 80 °C.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400. B Cycling performance of Li–S batteries at 0.1C at 80 °C. C The capacity comparison of np-ANF and Celgard TM 2400 membrane at different temperatures. D Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C after 500 cycles at 80 °C.

Article Snippet: When the current density increased stepwise, the discharge capacities of the np-ANF were 1249, 1140, 1032, 916, and 801 mA hg −1 at 0.2C, 0.5C, 1C, 2C, and 3C, respectively, with a capacity retention of around 60%, exhibiting a much better high-temperature rate performance than that of cell with Celgard TM 2400 membranes.

Techniques:

SEM images of the lithium electrode with np-ANF membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1) at a current density D 1 mA cm −2 and E 3 mA cm −2 . SEM images of the lithium electrode with Celgard TM 2400 membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1 at a current density ( F ), magnified image ( G ) 1 mA cm −2 and ( H ), and magnified image ( I ) 3 mA cm −2 .

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: SEM images of the lithium electrode with np-ANF membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1) at a current density D 1 mA cm −2 and E 3 mA cm −2 . SEM images of the lithium electrode with Celgard TM 2400 membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1 at a current density ( F ), magnified image ( G ) 1 mA cm −2 and ( H ), and magnified image ( I ) 3 mA cm −2 .

Article Snippet: When the current density increased stepwise, the discharge capacities of the np-ANF were 1249, 1140, 1032, 916, and 801 mA hg −1 at 0.2C, 0.5C, 1C, 2C, and 3C, respectively, with a capacity retention of around 60%, exhibiting a much better high-temperature rate performance than that of cell with Celgard TM 2400 membranes.

Techniques: Stripping Membranes

A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A Schematic configuration of a Li–S cell with a np-ANF membrane between the sulfur cathode and the lithium anode. B , C Photographs of an np-ANF membrane. D Thermogravimetric analysis curves for np-ANF membrane and Celgard TM 2400. E , F SEM images of the tip of lithium dendrite. G Stress–strain curves for np-ANF and Celgard TM 2400.

Article Snippet: Fig. 4 Electrochemical performance of the Li–S batteries with np-ANF and Celgard TM 2400 membrane.

Techniques:

XPS survey ( A ); Raman scattering spectra ( B ); SEM image, EDAX spectra, and the corresponding N and S element mapping images ( C ) for the np-ANF before and after adsorption test Li 2 S 4 solution followed by rinsing with DOL/DME solution and drying in a glovebox. D Diffusion of LPS in H-type cell through Celgard TM 2400 and np-ANF membrane.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: XPS survey ( A ); Raman scattering spectra ( B ); SEM image, EDAX spectra, and the corresponding N and S element mapping images ( C ) for the np-ANF before and after adsorption test Li 2 S 4 solution followed by rinsing with DOL/DME solution and drying in a glovebox. D Diffusion of LPS in H-type cell through Celgard TM 2400 and np-ANF membrane.

Article Snippet: Fig. 4 Electrochemical performance of the Li–S batteries with np-ANF and Celgard TM 2400 membrane.

Techniques: Adsorption, Diffusion-based Assay

A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles. F The decay per cycle of Li–S batteries with various membrane Table ); G Cycling performance of Li–S batteries at 0.1C at various sulfur loading. H Cycling performance Li–S batteries with np-ANF membrane at a rate of 0.2C after 500 cycles at sulfur loading of 5.8 mg cm −2 .

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A CV profiles with np-ANF at a scan rate of 0.1 mV s −1 ; B Cycling performance comparison of Li–S batteries with np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; C Galvanostatic charge–discharge profiles of np-ANF and Celgard TM 2400 membrane at a rate of 0.1C; D Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400; E Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C over a period of 3500 cycles. F The decay per cycle of Li–S batteries with various membrane Table ); G Cycling performance of Li–S batteries at 0.1C at various sulfur loading. H Cycling performance Li–S batteries with np-ANF membrane at a rate of 0.2C after 500 cycles at sulfur loading of 5.8 mg cm −2 .

Article Snippet: Fig. 4 Electrochemical performance of the Li–S batteries with np-ANF and Celgard TM 2400 membrane.

Techniques:

A Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400. B Cycling performance of Li–S batteries at 0.1C at 80 °C. C The capacity comparison of np-ANF and Celgard TM 2400 membrane at different temperatures. D Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C after 500 cycles at 80 °C.

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: A Rate performance of Li–S batteries ranged 0.1C to 3C with np-ANF and its comparison of Celgard TM 2400. B Cycling performance of Li–S batteries at 0.1C at 80 °C. C The capacity comparison of np-ANF and Celgard TM 2400 membrane at different temperatures. D Cycling performance Li–S batteries with np-ANF membrane at a rate of 3C after 500 cycles at 80 °C.

Article Snippet: Fig. 4 Electrochemical performance of the Li–S batteries with np-ANF and Celgard TM 2400 membrane.

Techniques:

SEM images of the lithium electrode with np-ANF membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1) at a current density D 1 mA cm −2 and E 3 mA cm −2 . SEM images of the lithium electrode with Celgard TM 2400 membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1 at a current density ( F ), magnified image ( G ) 1 mA cm −2 and ( H ), and magnified image ( I ) 3 mA cm −2 .

Journal: Nature Communications

Article Title: Multifactorial engineering of biomimetic membranes for batteries with multiple high-performance parameters

doi: 10.1038/s41467-021-27861-w

Figure Lengend Snippet: SEM images of the lithium electrode with np-ANF membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1) at a current density D 1 mA cm −2 and E 3 mA cm −2 . SEM images of the lithium electrode with Celgard TM 2400 membrane after 250 h cycles of stripping/plating in 1 mol/L LiCF 3 SO 3 DOL: DME v/v = 1/1 at a current density ( F ), magnified image ( G ) 1 mA cm −2 and ( H ), and magnified image ( I ) 3 mA cm −2 .

Article Snippet: Fig. 4 Electrochemical performance of the Li–S batteries with np-ANF and Celgard TM 2400 membrane.

Techniques: Stripping Membranes