Sodium-Based Batteries: In Search of the Best Compromise Between Sustainability and Maximization of Electric Performance

Karabelli, Duygu; Singh, Soumya; Kiemel, Steffen; Koller, Jan; Konarov, Aishuak; Stubhan, Frank; Miehe, Robert; Weeber, Max; Bakenov, Zhumabay; Birke, Kai Peter

doi:10.3389/fenrg.2020.605129

Cited by 38 publications

(35 citation statements)

References 99 publications

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“…Furthermore, due to the expected increasing number of Li-ion cells for the growing market of electrical vehicles and stationary storage for intermittent renewable energy sources, limited Lithium resources and higher costs may call for alternative elements in future decades. A promising alternative at least for stationary storage could be Sodium [6,7], which is cost effective without the limitation in the Li resources and exhibits comparable physicochemical and electrochemical properties.…”

Section: Introductionmentioning

confidence: 99%

Ionic and Thermal Transport in Na-Ion-Conducting Ceramic Electrolytes

et al. 2021

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We have studied the ionic and thermal transport properties along with the thermodynamic key properties of a Na-ion-conducting phosphate ceramic. The system Na1+xAlxTi2−x(PO4)3 (NATP) with x = 0.3 was taken as a NASICON-structured model system which is a candidate material for solid electrolytes in post-Li energy storage. The commercially available powder (NEI Coorp., USA) was consolidated using cold isostatic pressing before sintering. In order to compare NATP with the “classical” NASICON system, Na1+xZr2(SiO4)x(PO4)3−x (NaZSiP) was synthesized with compositions of x = 1.7 and x = 2, respectively, and characterized with regard to their ionic and thermal transport behavior. While ionic conductivity of the NaZSiP compositions was about more than two orders of magnitude higher than in NATP, the thermal conductivity of the NASICON compound showed an opposite behavior. The room temperature value was about a factor two higher in NATP compared to NaZSiP. While the thermal conductivity decreases with increasing temperature in NATP, it increases with increasing temperature in NaZSiP. However, the overall change of this thermal transport parameter over the measured temperature range from room temperature up to 800 °C appeared to be relatively small.

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Section: Introductionmentioning

confidence: 99%

Ionic and Thermal Transport in Na-Ion-Conducting Ceramic Electrolytes

et al. 2021

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“…(2) In conducting the above studies, particular emphasis should be put on the effect of the electrolyte as it is known that there is an intimate relationship between the safety of a Li-ion cell and the electrolyte it contains [6,12]. Some recent results on large-scale Na-ion cells indicate that Na-ion electrolytes utilising high weight fractions of thermally stable solvents such as PC or Tetraglyme can indeed result in lower rates of heat generation or higher thresholds for onset of exothermic self-heating reactions [65][66][67][68] (3) Recently, some articles have analysed the economic potential of Na-ion batteries from a materials perspective [19][20][21]. Detailed life-cycle cost estimations for Na-ion batteries, focussing on not just material costs or resource availability, but other factors such as costs of shipping/storing Na-ion cells at 0 V, relative to Li-ion cells at 30% SOC, and also their recycling, would certainly be timely and illuminating for the alkali-ion battery community…”

Section: Summary and Future Studiesmentioning

confidence: 99%

“…, as Al is not only much lighter than Cu but also cheaper[14,[19][20][21]. Unfortunately, Li alloys with Al to form Li x Al at low potentials vs. Li/Li + , thus requiring the need for Cu on the anode, as Li does not diffuse into Cu in appreciable quantities during normal operation of a rechargeable Liion cell…”

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confidence: 99%

Reviewing the Safe Shipping of Lithium-Ion and Sodium-Ion Cells: A Materials Chemistry Perspective

2021

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High energy density lithium-ion (Li-ion) batteries are commonly used nowadays. Three decades’ worth of intense research has led to a good understanding on several aspects of such batteries. But, the issue of their safe storage and transportation is still not widely understood from a materials chemistry perspective. Current international regulations require Li-ion cells to be shipped at 30% SOC (State of Charge) or lower. In this article, the reasons behind this requirement for shipping Li-ion batteries are firstly reviewed and then compared with those of the analogous and recently commercialized sodium-ion (Na-ion) batteries. For such alkali-ion batteries, the safest state from their active materials viewpoint is at 0 V or zero energy, and this should be their ideal state for storage/shipping. However, a “fully discharged” Li-ion cell used most commonly, composed of graphite-based anode on copper current collector, is not actually at 0 V at its rated 0% SOC, contrary to what one might expect—the detailed mechanism behind the reason for this, namely, copper dissolution, and how it negatively affects cycling performance and cell safety, will be summarized herein. It will be shown that Na-ion cells, capable of using a lighter and cheaper aluminum current collector on the anode, can actually be safely discharged to 0 V (true 0% SOC) and beyond, even to reverse polarity (negative voltages). It is anticipated that this article spurs further research on the 0 V capability of Na-ion systems, with some suggestions for future studies provided.

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“…The development of solid‐state sodium batteries (SSNaB) is driven by the need to address the ineluctable depletion of lithium resources that will follow the massive deployment of Li batteries for renewable energy storage [1–3] . Both Li + and Na + are isoelectronic, and have similar properties, [4, 5] but Na + is remarkably more abundant, making sodium much cheaper than lithium [6, 7] …”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] Both Li + and Na + are isoelectronic,and have similar properties, [4,5] but Na + is remarkably more abundant, making sodium much cheaper than lithium. [6,7] Solid polymer electrolytes (SPE) are polymers that can dissolve ionic species and allow ionic conductivity.P oly(ethylene oxide) (PEO) is the archetypal SPE for Li + .T he coordination of the Li + cation by the oxygen atoms of the polymer imparts solubility and separation from the counter anion. However,too strong acoordination leads to adecrease in cation mobility and transference number, both of which are detrimental to the stable operation of abattery.…”

Section: Introductionmentioning

confidence: 99%

The Unusual Conductivity of Na⁺ in PEO‐Based Statistical Copolymer Solid Electrolytes: When Less Means More

et al. 2021

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The lowc onductivity of Na + electrolytes in solid polymer electrolytes (SPEs) curtails the development of Na polymer batteries.I nt his study,N aClO 4 (3-24 wt %, 90-9:1 O:Na) is dissolved in statistical copolymers of ethylene oxide (EO) and propylene oxide (PO) (0-20 mol %). Remarkably, the conductivity of these SPEs increases as the concentration of Na + decreases,t hus departing from the usual Nernstian behavior.U sing ac ombination of calorimetric measurements and molecular dynamic simulations,this unusual phenomenon is attributed to the presence of physical cross-links generated by Na + .Asaresult, polymers containing alow salt concentration (3 wt %) displayadrastically enhanced ionic conductivity (up to 0.2 10 À4 Scm À1 at 25 8 8C), thus paving the way for the design of all-solid-state PEO-based sodium batteries operational at room temperature.

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Sodium-Based Batteries: In Search of the Best Compromise Between Sustainability and Maximization of Electric Performance

Cited by 38 publications

References 99 publications

Ionic and Thermal Transport in Na-Ion-Conducting Ceramic Electrolytes

Ionic and Thermal Transport in Na-Ion-Conducting Ceramic Electrolytes

Reviewing the Safe Shipping of Lithium-Ion and Sodium-Ion Cells: A Materials Chemistry Perspective

The Unusual Conductivity of Na⁺ in PEO‐Based Statistical Copolymer Solid Electrolytes: When Less Means More

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Sodium-Based Batteries: In Search of the Best Compromise Between Sustainability and Maximization of Electric Performance

Cited by 38 publications

References 99 publications

Ionic and Thermal Transport in Na-Ion-Conducting Ceramic Electrolytes

Ionic and Thermal Transport in Na-Ion-Conducting Ceramic Electrolytes

Reviewing the Safe Shipping of Lithium-Ion and Sodium-Ion Cells: A Materials Chemistry Perspective

The Unusual Conductivity of Na+ in PEO‐Based Statistical Copolymer Solid Electrolytes: When Less Means More

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The Unusual Conductivity of Na⁺ in PEO‐Based Statistical Copolymer Solid Electrolytes: When Less Means More