Kooperativer Bibliotheksverbund

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2018-02, No. 1 ( 2018-07-23), p. 16-16

Abstract: We report on a particularly stable 3 V all-solid-state sodium–ion battery built using a closo-borate based electrolyte, namely Na 4 (B 12 H 12 )(B 10 H 10 ). The battery employs a sodium metal anode and a NaCrO 2 cathode. Battery performance is enhanced through the creation of an intimate cathode–electrolyte interface resulting in reversible and stable cycling with a capacity of 85 mAh/g at C/20 and 80 mAh/g at C/5 with more than 90% capacity retention after 20 cycles at C/20 and 85% after 250 cycles at C/5. We also discuss the effect of cycling outside the electrochemical stability window and show that electrolyte decomposition leads to faster though not critical capacity fading. Our results demonstrate that owing to their high stability and conductivity closo-borate based electrolytes could play a significant role in the development of a competitive all-solid-state sodium–ion battery technology. L. Duchêne, R.-S. Kühnel, D. Rentsch, A. Remhof, H. Hagemann, C. Battaglia, Chem. Comm. 2017, 53, 4195 L. Duchêne, R.-S. Kühnel, E. Stilp, E. Cuervo Reyes, A. Remhof, H. Hagemann, C. Battaglia, Energy & Environmental Science 2017, 10, 2609

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2018-02/1/16

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2018

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2010-02, No. 9 ( 2010-07-08), p. 596-596

Abstract: Abstract not Available.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2010-02/9/596

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2010

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2011-02, No. 17 ( 2011-08-01), p. 1254-1254

Abstract: Abstract not Available.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2011-02/17/1254

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2011

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2020-02, No. 45 ( 2020-11-23), p. 3806-3806

Abstract: Water-in-salt electrolytes have enabled the development of novel high-voltage aqueous lithium-ion batteries due to their high electrochemical stability compared to traditional aqueous electrolytes.[1, 2] The development of equivalent sodium electrolytes is hindered by two factors: Low solubility of suitable sodium salts. For example, NaTFSI has a solubility at room temperature of only 8 mol/kg compared to 21 mol/kg for LiTFSI.[3] A higher salt concentration is needed to reach the same level of electrochemical stability due to the lower charge density of Na + compared to Li + .[4] In this study, we screen 〉 100 combinations of up to five sodium salts with water to identify highly concentrated solutions that are thermodynamically in the liquid state at ≤25 °C.[5, 6] An additional criterion for a stable water-in-salt electrolyte is a high content of SEI-forming anions. Furthermore, we find that the electrochemical stability of the electrolyte benefits from anions that are only weakly coordinating. In fact, we discovered a strong correlation between the stability of the electrolyte and the position of the anion in the Hofmeister series.[6] Our findings led to the development of multiple 2 V-class sodium-ion batteries with Coulombic efficiencies of up to 99.8% during cycling at a rate of 1C and record-high energy densities for such devices of up to 77 Wh/kg based on the active masses of both anode and cathode.[6] [1] L. Suo, O. Borodin, T. Gao, M. Olguin, J. Ho, X. Fan, C. Luo, C. Wang, K. Xu, Science 350 (2015) 938–943. [2] Y. Yamada, K. Usui, K. Sodeyama, S. Ko, Y. Tateyama, A. Yamada, Nat. Energy 1 (2016) 16129. [3] R.-S. Kühnel, D. Reber, C. Battaglia, ACS Energy Lett. 2 (2017) 2005–2006. [4] D. Reber, R. Figi, R.-S. Kühnel, C. Battaglia, Electrochim. Acta 321 (2019) 134644. [5] D. Reber, R.-S. Kühnel, C. Battaglia, ACS Mater. Lett. 1 (2019) 44–51. [6] D. Reber, M. Becker, R.-S. Kühnel, C. Battaglia, submitted.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2020-02453806mtgabs

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2020

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2014-02, No. 7 ( 2014-08-05), p. 534-534

Abstract: Ionic liquids (ILs) are presently considered as one of the most promising candidates for the replacement of organic carbonates as electrolytes in lithium-ion batteries (LIBs). The main advantages of ILs towards organic carbonates are the high thermal, chemical and electrochemical stability as well as the negligible vapor pressure and the reduced flammability [1]. So far, several aprotic ionic liquids (AILs) have been investigated as electrolytes for LIBs. The results of these studies showed that AILs can be successfully introduced in LIBs, and their use has beneficial effects on the safety as well as on the temperature range of use of these devices [2,3] . Nevertheless, AILs are rather expensive and the performance of AIL-based LIBs still needs to be improved in order to be fully competitive with that of conventional electrolytes. Such improvement is particularly necessary for applications where high current densities are needed. In these applications the reduced lithium-ion transport of AIL-based electrolytes, compared to that of conventional electrolytes, might significantly affect the rate performance of LIBs [3]. For these reasons, the development of new IL-based electrolytes with improved lithium-ion mobility compared to the one of present AIL-based electrolytes appears nowadays of importance for the introduction of ILs in LIBs. Taking into account the high costs of AILs, it would also be very beneficial to develop cheaper ILs, as they could be easier introduced in commercial devices. Protic ionic liquids (PILs) are a subset of ILs and they are typically synthesized by neutralization reactions of a Brønsted acid (proton donor) and a Brønsted base (proton acceptor) [1]. PILs display all favorable properties of ILs, but they have the advantage of being easier to synthesize and cheaper compared to AILs [1, 4] . Clearly, these properties make them interesting candidates for the use as electrolyte component for electrochemical devices. In the past, the use of PILs as electrolyte for LIBs was not considered. The availability of an acidic proton and their strong reactivity towards lithium were seen as an obstacle for the introduction of PILs into these devices, and consequently all efforts were focused on AILs. Nevertheless, we recently showed that in dry PILs the labile proton of the cation is not “free” and these cations are not subject to reversible protonation-deprotonation [4]. We also proved that battery materials, e.g. lithium iron phosphate (LFP), can be used in combination with dry PILs without being subject to structural changes. Moreover, we showed that lithium-ion batteries containing PIL-based electrolytes can be realized and that they display promising performance in terms of capacity and cycling stability [4] . Taking into account these results, PILs can therefore be regarded as a new class of electrolytes for LIBs. In this work we considered two pyrrolidinium-based PILs in view of their use as electrolyte for LIBs. We showed that (dry) PILs-based electrolytes display conductivity, viscosity and lithium-ion self-diffusion coefficient comparable to those of a pyrrolidinium-based AIL. However, they have the important advantage of displaying an improved performance when used in combination with battery materials, e.g. lithium vanadium phosphate (LVP), during tests at high C-rate. The lithium ions in PIL-based electrolytes do not move faster than in AIL-based electrolytes according to their self-diffusion coefficients [5] . However, fewer TFSI - anions form the solvation sphere of Li + in the investigated PILs. We showed that the improved performance of LVP electrodes in the PIL-based electrolytes is related to a reduced charge-transfer resistance at the LVP-electrolyte interface. Taking into account that the limited performance at high rate of IL-based LIBs is presently considered as one of the main limitations of these devices, the use of PIL-based electrolytes can be regarded as a new and promising strategy to overcome this drawback. Additionally, since PILs are typically cheaper than AILs, the introduction of this innovative electrolyte could also be of importance for the development of safe and cheaper IL-based lithium-ion batteries. References [1] P. Wasserscheid, Handbook of Green Chemistry, Volume 6: Ionic Liquids Handbook of green chemistry, 2010. [2] D.R. McFarlane, J. Sun, J. Golding, P. Meakin, M. Forsyth, Electrochim. Acta, 45 (2000) 1271-1278. [3] S. Menne, R.S. Kühnel, A. Balducci, Electrochim. Acta, 90 (2013) 641-648. [4] S. Menne, J. Pires, M. Anouti, A. Balducci, Electrochem. Commun., 31 (2013) 39-41. [5]. T. Vogl, S. Menne, R.-S Kühnel, A. Balducci, J. Mat. Chem. A, DOI:10.1039/C3TA15224C

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2014-02/7/534

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2014

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2018-01, No. 3 ( 2018-04-13), p. 404-404

Abstract: Due to their inherent safety, environmental friendliness, and potential low cost, rechargeable batteries based on aqueous electrolytes are being developed as a large-scale energy storage option for grid applications to enable wide spread integration of renewables. In this field cost and safety are more important than energy density, which is why water based systems are a promising candidate. So far, operational voltages of aqueous batteries have been too low to enable market penetration due to the narrow electrochemical stability window of water (~1.23 V). Using highly-concentrated aqueous sodium bis(fluorosulfonyl)imide (NaFSI) solutions (35m), we recently reported a stability window of 2.6 V on stainless steel current collectors 1 . Meanwhile addressing the raw materials supply chain as important challenge for scaling, we developed an aqueous sodium-ion battery employing only non-critical raw materials, namely NaTi 2 (PO 4 ) 3 2 and Na 3 (VOPO 4 ) 2 F 3 on the anode and cathode side, respectively. The average discharge voltage is 1.5 V, whereas the 35-molal NaFSI aqueous electrolyte allowed us to use the full capacity of the high-voltage cathode material. Due to the enhanced oxidative stability of the electrolyte, this battery displays an energy density that is almost twice as high as that of previously reported aqueous sodium-ion batteries 4 . Kühnel, R. S.; Reber, D.; Battaglia, C., A High-Voltage Aqueous Electrolyte for Sodium-Ion Batteries. ACS Energy Lett. 2017, 2 , 2005. Li, Z.; Young, D.; Xiang, K.; Carter, W. C.; Chiang, Y.-M., Towards High Power High Energy Aqueous Sodium-Ion Batteries: The NaTi 2 (PO 4 ) 3 /Na 0.44 MnO 2 System. Adv. Energy Mater. 2013, 3 , 290. Qi, Y.; Mu, L.; Zhao, J.; Hu, Y. S.; Liu, H.; Dai, S., Superior Na-Storage Performance of Low-Temperature-Synthesized Na 3 (VO( 1-x )PO 4 ) 2 F(1+2x) (0≤x≤1) Nanoparticles for Na-Ion Batteries. Angew. Chem. Int. Ed. 2015, 54 , 9911. Kumar, P. R.; Jung, Y. H.; Wang, J. E.; Kim, D. K., Na 3 V 2 O 2 (PO 4 ) 2 F-MWCNT nanocomposites as a stable and high rate cathode for aqueous and non-aqueous sodium-ion batteries. J. Power Sources 2016, 324 , 421.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2018-01/3/404

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2018

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2016-02, No. 34 ( 2016-09-01), p. 2208-2208

Abstract: While the size of electronic components has shrunk dramatically over the last few decades, the footprint of autonomous electronic devices is today often limited by the battery. Miniaturization of batteries is challenging in particular when using liquid electrolytes based on organic solvents. All-solid-state batteries employing solid-state electrolytes promise to facilitate miniaturization and integration. Current developments of solid-state electrolytes for lithium ion batteries focus mainly on oxide- and thiophosphate-based compounds, but have not yet enabled the fabrication of a competitive all-solid-state battery. We recently reported the discovery of a superionic phase at room temperature in the class of lithium amide-borohydrides, enabling ionic conductivities comparable to values of common organic liquid electrolytes. We demonstrate good rate performance up to 5C and stable cycling over 400 cycles at 1C in a lithium titanate half-cell battery configuration, indicating high bulk and interfacial stability. Our results demonstrate the potential of lithium amide-borohydrides as solid-state electrolytes for scalable high-power lithium ion batteries.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2016-02/34/2208

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2016

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2017-01, No. 3 ( 2017-04-15), p. 246-246

Abstract: All-solid-state lithium-ion batteries employing solid-state electrolytes promise higher operational safety, enhanced temperature stability, potentially higher cell voltages, and consequently higher energy density compared to traditional batteries with liquid electrolytes based on flammable organic solvents. So far, only a few oxide- and thiophosphate-based solid-state electrolytes exhibit lithium ion conductivities near room temperature comparable to liquid organic electrolytes. However, none of these electrolytes has enabled the fabrication of a competitive all-solid-state battery yet. Here we report the discovery of a superionic phase near room temperature in the class of lithium amide-borohydrides, enabling ionic conductivities of 8 mS/cm near room temperature, comparable to values of common organic liquid electrolytes. The transition into the superionic phase is demonstrated to be triggered by melting of a fully occupied lithium sublattice into a symmetry-equivalent interpenetrating dual sublattice consisting of lithium vacancy sites. We further demonstrate excellent rate performance up to 5C and stable cycling over 400 cycles at 1C of our solid-state electrolytes in half-cell battery configuration representing an important step towards a viable solid-state battery technology.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2017-01/3/246

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2017

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2018-01, No. 44 ( 2018-04-13), p. 2516-2516

Abstract: Replacing the acetonitrile-based electrolyte in state-of-the-art supercapacitors by an aqueous electrolyte could make these devices environmentally more benign, improve operational safety, and render supercapacitors potentially more cost efficient. The narrow electrochemical stability window of water (~1.23 V) is the main challenge in order to increase the energy density of water based devices. Recently it was reported that ultra-highly concentrated aqueous salt solutions can provide stability windows up to 3 V 1 . Salt concentrations higher than 21 mol kg -1 lead to increased kinetic stability, but result in reduced ionic conductivities of typically less than 10 mS cm -1 . This renders such systems unsuitable for high power applications such as supercapacitors. In a recent study, we report beneficial effects in terms of electrochemical stability and conductivity for a moderately concentrated 8m NaTFSI aqueous solution 2 . Following a stringent test procedure, the stability window was determined to be 1.8 V and an ionic conductivity of 48 mS cm -1 was obtained, the latter being on par with modern organic electrolytes. A 1.8 V carbon/carbon supercapacitor displayed high maximum energy density of 14.4 Wh kg -1 on the activated carbon mass level and stable cycling over 100,000 cycles. Redox active potassium iodide was added to the system in order to boost its maximum specific energy to the very high value of 37.8 Wh kg -1 , which is comparable to the performance of currently available commercial acetonitrile based supercapacitors. Suo, L.; Borodin, O.; Gao, T.; Olguin, M.; Ho, J.; Fan, X.; Luo, C.; Wang, C.; Xu, K., "Water-in-salt" electrolyte enables high-voltage aqueous lithium-ion chemistries. Science 2015, 350 , 938. Reber, D.; Kühnel, R.-S.; Battaglia, C., High-voltage aqueous supercapacitors based on NaTFSI. Sustainable Energy Fuels 2017 , doi: 10.1039/C7SE00423K

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2018-01/44/2516

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2018

detail.hit.zdb_id: 2438749-6

In: ECS Meeting Abstracts, The Electrochemical Society, Vol. MA2022-02, No. 2 ( 2022-10-09), p. 161-161

Abstract: The water-in-salt concept has significantly improved the electrochemical stability of aqueous electrolytes, and the hybridization with organic solvents or ionic liquids has further enhanced their reductive stability. [1] Here, we open a large design space by introducing succinonitrile as a cosolvent in water/ionic liquid/succinonitrile hybrid electrolytes. Via addition of the nitrile, electrolyte performance metrics such as electrochemical stability, conductivity, or cost can be tuned, and salt solubility limits can be fully circumvented. We elucidate the solution structure of two select hybrid electrolytes and highlight the impact of each electrolyte component on the final formulation, showing that excess ionic liquid fractions decrease the lithium transport number, while excess nitrile addition reduces electrochemical stability and yields flammable electrolytes. If component ratios are tuned appropriately, high electrochemical stability is achieved and aqueous Li 4 Ti 5 O 12 - LiNi 0.8 Mn 0.1 Co 0.1 O 2 full cells show excellent cycling stability with a maximum energy density of ca. 140 Wh/kg of active material, and Coulombic efficiencies of close to 99.5% at 1C. Furthermore, strong rate performance over a wide temperature range, facilitated by the fast conformational dynamics of succinonitrile, with a capacity retention of 53% at 10C relative to 1C is observed. [2] References: [1] Becker, M.; Rentsch, D.; Reber, D.; Aribia, A.; Battaglia, C.; Kühnel, R.-S., The hydrotropic effect of ionic liquids in water‐in‐salt electrolytes. Angew. Chem. Int. Ed.. 2021 , 60 , 14100. [2] Reber, D.; Borodin, O.; Becker, M.; Rentsch, D.; Thienenkamp, J.H.; Grissa, R.; Zhao, W.; Aribia, A.; Brunklaus, G.; Battaglia, C.; Kühnel, R.-S., Water/Ionic Liquid/Succinonitrile Hybrid Electrolytes for Aqueous Batteries. Adv. Funct. Mater. 2022 , 2112138.

Type of Medium: Online Resource

ISSN: 2151-2043

URL: Article

DOI: 10.1149/MA2022-022161mtgabs

Language: Unknown

Publisher: The Electrochemical Society

Publication Date: 2022

detail.hit.zdb_id: 2438749-6