/ Home
/ SUBMISSION

/ The BJNANO
/ Diamond Open Access
/ Journal Statistics
/ Editorial Board
/ Community
/ Call for papers

/ Latest Articles
/ Most accessed
/ Thematic issues
/ Volumes
/ Authors

/ Alerts

/ TWITTER
/ LINKEDIN
/ Mastodon
/ RSS FEED

Empty search

Article Type

Publication Date Range

Search Tips

This search combines search strings from the content search (i.e. "Full Text", "Author", "Title", "Abstract", or "Keywords") with "Article Type" and "Publication Date Range" using the AND operator.

Search Examples

aromatic	the word “aromatic”
aromatic aldehyde	the word “aromatic” OR “aldehyde”
+aromatic +aldehyde	both words “aromatic” AND “aldehyde”
+aromatic -aldehyde	the word “aromatic” but NOT “aldehyde”
“aromatic aldehyde”	the exact phrase “aromatic aldehyde”
benz*	words which begin with “benz”, such as “benzene” or “benzyl”
benz*yl	words that begin with “benz” and end with “yl”, such as “benzyl” or “benzoyl”
benzyl~	words that are close to the word “benzyl”, such as “benzoyl” (i.e., fuzzy search)

Search results

Search for "sodium–sulfur battery" in Full Text gives 2 result(s) in Beilstein Journal of Nanotechnology.

Progress and innovation of nanostructured sulfur cathodes and metal-free anodes for room-temperature Na–S batteries

Marina Tabuyo-Martínez,
Bernd Wicklein and
Pilar Aranda

Beilstein J. Nanotechnol. 2021, 12, 995–1020, doi:10.3762/bjnano.12.75

commercially available for room-temperature applications [10]. The first commercialized Na–S battery was a high-temperature sodium–sulfur battery, which has an operational temperature in the range of 270–350 °C [13]. It was launched to the market by NGK Insulator Co. in Japan in 2002. However, these devices

PDF

Figure 1: (A) Schematic representation of the electrochemical processes taking place in a RT Na–S battery. Figure 1A w...

Jump to Figure 1

Figure 2: Some of the principal challenges of RT Na–S batteries and potential improvements by nanostructuring...

Jump to Figure 2

Figure 3: (A) Schematic illustration of the processing steps of using sucrose to produce microporous, sulfur-...

Jump to Figure 3

Figure 4: (A) Schematic illustration of preparation and structure of the covalent sulfur–carbon composite syn...

Jump to Figure 4

Figure 5: (A) Schematic representation of a RT Na–S battery with a liquid-phase catholyte containing polysulf...

Jump to Figure 5

Figure 6: (A) Cycling performance of a sulfur–hollow carbon nanospheres cathode composite with and without co...

Jump to Figure 6

Figure 7: (A) HRTEM image of sulfur nanoparticles and graphene in GCNT/S and the cycle performance at 1 A·g⁻¹...

Jump to Figure 7

Figure 8: (A) Illustration of the Na dendrite formation mechanism during charging cycles, where Na is redepos...

Jump to Figure 8

Figure 9: (A) Encapsulation of molten metallic Na into porous carbonized wood by a spontaneous infusion. SEM ...

Jump to Figure 9

Figure 10: (A) Illustration of the sodiation process of a flexible Sn@C composite substrate and corresponding ...

Jump to Figure 10

Album

Review

Published 09 Sep 2021

Full text

From lithium to sodium: cell chemistry of room temperature sodium–air and sodium–sulfur batteries

Philipp Adelhelm,
Pascal Hartmann,
Conrad L. Bender,
Martin Busche,
Christine Eufinger and
Juergen Janek

Beilstein J. Nanotechnol. 2015, 6, 1016–1055, doi:10.3762/bjnano.6.105

battery; lithium–sulfur battery; sodium–oxygen battery; sodium–sulfur battery; Review 1 Introduction Rechargeable lithium-ion batteries (LIBs) have rapidly become the most important form of energy storage for all mobile applications since their commercialization in the early 1990s. This is mainly due to

PDF

Figure 1: Theoretical and (estimated) practical energy densities of different rechargeable batteries: Pb–acid...

Jump to Figure 1

Figure 2: Operating principles of (a) a lithium-ion battery, (b) a metal–oxygen battery (non-aqueous electrol...

Jump to Figure 2

Figure 3: (a) The Li–O phase diagram. (b) The Na–O phase diagram. Figure redrawn based on [18] and [19].

Jump to Figure 3

Figure 4: Matrix for classifying voltage profiles of metal–oxygen batteries. Type 1A is the ideal case. Frequ...

Jump to Figure 4

Figure 5: DEMS analysis of Li/O₂ cells with different electrolyte compositions, namely a mixture of propylene...

Jump to Figure 5

Figure 6: Sketch by Thotiyl et al. illustrating their findings on the oxidation of the carbon electrode. At d...

Jump to Figure 6

Figure 7: SEM image of toroidal Li₂O₂ nanoparticles on a carbon fiber (10 µm in diameter) that form as a disc...

Jump to Figure 7

Figure 8: Illustration of TEMPO as a redox mediator (RM) in an Li/O₂ cell reversibly catalyzing the Li₂O₂ oxi...

Jump to Figure 8

Figure 9: Literature timeline of research papers on aprotic sodium–oxygen batteries (ranked after date of acc...

Jump to Figure 9

Figure 10: Sketch of the first room temperature sodium–oxygen cell and its discharge and charge potentials dur...

Jump to Figure 10

Figure 11: Discharge/charge curves (Type 1B) of a sodium–oxygen battery with NaO₂ as discharge product. The ma...

Jump to Figure 11

Figure 12: The thermodynamic landscape of (a) sodium– and (b) lithium–oxygen cells. All values are calculated ...

Jump to Figure 12

Figure 13: Voltage hysteresis of different carbon materials for the cathode of a sodium oxygen cell (left), fi...

Jump to Figure 13

Figure 14: Voltage profiles of Na/O₂ cells under static gas atmosphere and flowing gas atmosphere (Type 1B/3B)...

Jump to Figure 14

Figure 15: Literature overview on different studies of Na/O₂ cells. The comparison shows the voltage profile o...

Jump to Figure 15

Figure 16: (a) The Li–S phase diagram. (b) The Na–S phase diagram. Redrawn from references [129,130]. The Na–S phase di...

Jump to Figure 16

Figure 17: Schematic illustration of the reduction processes at the negative electrode during discharge of a L...

Jump to Figure 17

Figure 18: Schematic illustration of the polysulfide shuttle mechanism after Mikhaylik and Akridge [123]. Long poly...

Jump to Figure 18

Figure 19: Typical voltage profile of a lithium/sulfur cell. A similar behavior can be expected for an analogo...

Jump to Figure 19

Figure 20: Schematic diagram of the interconnected pore structure of mesoporous CMK-3 impregnated with sulfur ...

Jump to Figure 20

Figure 21: Operando X-ray absorption near-edge spectroscopy (XANES) measurements (left) during first charge an...

Jump to Figure 21

Figure 22: Literature timeline of research papers on room temperature Na/S₈ batteries (ranked after date of ac...

Jump to Figure 22

Figure 23: (a) First discharge–charge curve of a Na/S₈ battery with liquid electrolyte at room temperature and...

Jump to Figure 23

Figure 24: (a) Voltage profiles a of Na/S₈ cells with a TEGDME-based electrolyte and a nanostructured carbon/s...

Jump to Figure 24

Figure 25: Room temperature sodium–sulfur battery based on shallow cycling between sulfur and soluble long cha...

Jump to Figure 25

Figure 26: Literature overview on different studies of Na/S₈ cells with liquid electrolyte operating at room t...

Jump to Figure 26

Album

Review

Published 23 Apr 2015

Full text

Other Beilstein-Institut Open Science Activities

/ Help / Support & Contact / Alerts / Privacy Policy / Terms & Conditions / Impressum