WO2016157083A1 - An electrochemical solid carbon-sulfur na-ion based device and uses thereof - Google Patents

Abstract

The present disclosure relates to the development layered electrochemical solid devices, in particular to the development of a new device; a supercapacitor and or a battery solid carbon- sulfur Na-ion glassy electrolyte based device with autonomous dual functionality comprising a safe, environmentally friendly and inexpensive device. The present subject-matter relates to a layered electrochemical solid device comprising a positive electrode current collector, a positive electrode, a glass electrolyte, a negative electrode and a negative electrode current collector wherein the positive electrode current collector comprises aluminum; the positive electrode comprises sulfur, glass electrolyte and carbon; the electrolyte composition comprises a compound of formula Na_3-2xM_xHalO or Na₃- _3xM_xHalO wherein: M is selected from the group consisting of boron, aluminum, magnesium, calcium, strontium, barium; Hal is selected from the group consisting of fluoride, chloride, bromide, iodide or mixtures thereof; X is the number of moles of M and 0 ˂ x ≤ 0.01; the negative electrode comprises a carbonaceous material; the negative electrode current collector comprises copper. The present subject-matter relates to a layered electrochemical solid device comprising the above described layers with inverted roles.

Description

D E S C R I P T I O N

AN ELECTROCHEMICAL SOLID CARBON-SULFUR NA-ION BASED DEVICE AND USES THEREOF Technical field

[0001] The present disclosure relates to the development and improvement of sodium-ion electrochemical devices, in particular to the development of a new device; a supercapacitor and a supercapacitor and battery solid carbon-sulfur Na-ion based device with autonomous dual functionality which is charged from the Na-rich glassy electrolyte solid electrolyte glass comprising a safe, environmentally friendly and inexpensive device. The present dual mode of operation, both a high energy battery mode and power capacity supercapacitor mode along with a burst discharge of less or equal to 1 second. I n the supercapacitor mode of a device, it can store more energy than any other known capacitor and in the battery mode several of the present devices stored more energy for a longer period than most Na-ion batteries.

Background Art

[0002] Since the advent of energy storage, humankind has been seeking a combined high power, high energy storage solution in a single device. Considerable efforts have been expended on the development of high-performance energy-storage devices such as Lithium-ion capacitors (LICs), Lithium-ion batteries (LIBs) and, lately, Sodium-ion batteries (N I Bs). High performance energy storage devices such as supercapacitors and batteries rely on different fundamental working principles - bulk versus surface - electron conduction and/or ion diffusion corresponding to electrochemical versus electrostatic energy storage (1 ). Electric double-layer capacitors (EDLCs), which store energy through accumulation of ions on the electrodes' interface, have low energy storage capacity but very high power density. However, in hybrid capacitors (1-5) like LICs, despite their recent advancement, the imbalance in kinetics between the two electrodes still remains a major drawback. Here it is presented an energy storage cell with two energy storage modes which can operate as a supercapacitor or a supercapacitor and sodium battery (6-8);

[0003] This device will impact a very broad spectrum of applications especially in the transportation, grid stationary, and aerospace. [0004] Ford Motor pioneered the molten salt Na-S battery in Ford's "Ecostar" 1971, to power early-model electric cars (9). Lately, developments with NASICON membrane allowed operation at 90 °C with all components remaining solid (10). Because of its high energy density, the Na-S battery has been proposed for space applications (11,12). Sodium-sulfur cells can be made space-qualified; in fact a test Na-S r cell was flown on the Space Shuttle. The Na-S flight experiment demonstrated a battery with a specific energy of 150 Wh/kg (3 x Ni-MH battery energy density), operating at 350 °C. It was launched on the STS-87 mission in November 1997, and demonstrated 10 days of experiment operation in orbit (13). As highlighted above, molten salt Na-S batteries can be deployed to support the electric grid. In 2010, Presidio, Texas built the world's largest sodium- sulfur battery, which can provide 4 MW of power for up to eight hours when the city's lone line to the Texas power grid goes down (14). Under some market conditions, Na-S batteries provide value via energy arbitrage (charging battery when electricity is abundant/cheap, and discharging into the grid when electricity is more valuable) and voltage regulation (15). Na-S batteries are a possible energy storage technology to support renewable energy generation, specifically wind farms and solar generation plants. In the case of a wind farm, the battery would store energy during times of high wind but low power demand. This stored energy could then be discharged from the batteries during peak load periods. In addition to this power shifting, it is likely that Na-S batteries could be used throughout the day to assist in stabilizing the power output of the wind farm during wind fluctuations. These types of batteries present an option for energy storage in locations where other storage options are not feasible. For example, pumped-storage hydroelectricity facilities require significant space and water resources, while compressed air energy storage (CAES) requires some type of geologic feature such as a salt cave (16).

[0005] Sodium-ion batteries (NIBs) have been gaining increasing attention thanks to the natural abundance and low toxicity of sodium resources (6-8). Furthermore, sodium is located just below lithium in the s block. Therefore, similar chemical approaches including a synthetic strategy, intercalation/alloying/conversion chemistry, and characterization methods utilized in electrode materials for LIBs could be applied to develop electrode materials for NIBs. Despite potential disadvantages, including larger size (0.98-1.02 A) of Na cations (approximately, 20-25% larger than Li cations, 0.76-0.78 A) and higher redox potential (-2.71 V vs. SHE) of Na/Na⁺ compared to Li analogues (-3.04 V vs. SHE) of Li/Li⁺ (17), the different interactions between the guest Na-cations and the host crystal structures can influence the kinetics as well as thermodynamic properties of NIBs, and this may provide an avenue for a breakthrough technology to surpass LIBs (18). As an effort to find alternatives to graphite in NIBs, Doeff et al. demonstrated the reversible de/insertion of Na ions into disordered carbons for an anode in NIBs (19). Most of the sodium ions are electrochemically inserted into nanoporous voids of hard carbon (HC), which is built by disordered graphene stacking - the so-called 'house of cards' type model. Two independent research groups lead by Dahn (20) and Tirado (21) demonstrated that the initial specific capacity of hard carbon in NIBs is ca. 300 mAh/g close to that of graphite in LIBs. Most of the reversible capacity is related to sodium storage inside nanocavities. However, this hard carbon electrode exhibited significant loss of capacity within 10 cycles with poor rate performance.

[0006] In the simplest configuration an EDLC consists of two electrodes immersed into a liquid electrolyte and separated by a membrane. Upon application of a voltage difference to the electrodes, the ions of the opposite charge of the electrolyte accumulate on the electrodes' interface in a quantity proportional to the applied voltage, forming a double layer capacitor (2). The charge storage mechanism in a typical EDLC is not Faradaic, which means that during the charge and discharge of this type of device, no charge transfer takes place across the electrolyte/electrode interface and the energy storage is of an electrostatic nature. In LICs, electrodes' carbonaceous materials may additionally exhibit chemical interactions with selected electrolytes, which involve fast and often reversible charge-transfer reactions between the carbon surface and the electrolyte ions; such processes are Faradaic. At a constant temperature and voltage, the ionic density on the carbon electrode surface is controlled by a balance between the changes in entropy and enthalpy of the system (3). The sodium ion capacitors, NICs, were not studied in detail; it is expected that some of their properties can be inferred from LICs properties. The maximum voltage in an EDLC is generally determined by the electrochemical stability window of the selected electrolyte. Impurities and functional groups on carbon, however, may catalyze electrolyte decomposition, narrowing the operating voltage window.

[0007] Batteries on the other hand are composed by electrochemical cells. Each cell consists of positive and negative electrode separated by an electrolyte. Once the electrodes are connected externally, there are chemical reactions that occur at both electrodes, liberating electrons and enabling the current to be tapped by the user (22).

[0008] These facts are disclosed in order to illustrate the technical problem addressed by the present disclosure. General Description

[0009] The present disclosure relates to the development and improvement of sodium-ion electrochemical devices, in particular to the development of a new device, a supercapacitor and battery solid carbon-sulfur Na-ion based device with autonomous dual functionality which is uniquely charged from the Na-rich glassy electrolyte solid electrolyte glass comprising a safe, environmentally friendly and inexpensive device. In the supercapacitor mode of a device, it can store more energy than any other known capacitor and in the battery mode several of devices stored more energy for a longer period than most Na-ion batteries.

[0010] In an embodiment, the present disclosure relates to a supercapacitor and battery solid carbon-sulfur Na-ion based device with autonomous dual functionality and charged from the Na- rich glassy electrolyte.

[0011] In some cases, the collectors can have a predominant role. They can function as electrodes being the copper + carbon black the positive electrode and the sulfur + glass electrolyte + carbon in aluminum the negative electrode. This configuration makes the device works reversely to what was described for charge and discharge.

[0012] A supercapacitor and battery solid carbon-sulfur Na-ion based device with autonomous dual functionality which is uniquely charged from the Na-rich glassy electrolyte is now disclosed. Unlike the molten salt battery, Na-S, constructed from liquid sodium and sulfur, which operates at temperatures of 300 to 350 °C and generates highly corrosive sodium polysulfides, and therefore primarily suited to large-scale non-mobile applications such as grid energy storage; the devices now disclosed are environmentally friendly and inexpensive and so not present any of the previous cited risks of molten Na-S batteries. They operate at room temperature and do not exhibit any polysulfides 'shuttle' problems associated with this chemistry, and therefore these devices have a prolonged cycle life. They present a dual mode of operation, both a high energy battery mode and a power capacity supercapacitor mode along with a burst discharge of one (1) second.

[0013] In the supercapacitor mode of a device, it can store more energy than any other known capacitor and in the battery mode, the devices now disclosed stored more energy for a longer period than most Na-ion batteries. The devices now disclosed are safe and therefore will have numerous advantages in a multitude of markets such as mobile applications and grid energy storage.

[0014] A supercapacitor and battery solid carbon-sulfur Na-ion based device with autonomous dual functionality and charged from the Na-rich glassy electrolyte are now disclosed. [0015] This disclosure presents a solid state bulk energy storage device working autonomously, simultaneously or independently as a supercapacitor and as a battery; although predominantly as a supercapacitor. On charge, the supercapacitor is the last mode to be fully charged and on discharge, the supercapacitor mode is the first to be discharged. The device is composed of a copper bulk collector, a negative electrode of carbon black (C) which is mostly disordered graphite (Fig. 1), a doped glassy electrolyte Na₃CIO based, a positive electrode comprised of a mixture of: sulfur (Ss), a glassy electrolyte, and carbon black, deposited on an aluminum bulk collector. If some sulfur reacts with the electrolyte, during electrode preparation, it is most likely just at the surface forming an amorphous phase that cannot be distinguished from the other amorphous phases already present (glassy electrolyte and carbon black, Fig. 1). The surface dimensions of the cells' electrodes are 2.5x2.5 cm² with a loading of 0.20-0.40 g/cm² of electrode materials and electrolyte. The sulfur loading can be 0.018-0.040 g/cm². Collectors have an extended functionality; besides being an electronic transport media, they have a support and heat dissipation functionality which is not intrinsic to the device. The cells have 0.15-0.35 g/cm² of electrolyte as separator. The cell's thickness is 0.15-0.35 cm. The electrodes, electrolyte and collectors were accountable to the device's weight.

[0016] A glassy-electrolyte of the same family, Li₃CIO, was previously characterized (23).

[0017] The Na₃CIO based glassy electrolyte's high ionic conductivity enables the fabrication of solid state energy devices with bulk (thick) layers of electrolyte, enabling existing battery coating methods. The Na-rich transport characteristics of the electrolyte permit enhanced cell component kinetics and increased life cycle. Moreover, the battery mode is charged/discharged from the electrolyte and in the sulfurbased electrode the Na-ions do not cross the electrode's surface allowing for a new set of electrode combinations such as the carbon-sulfur pair presented herein. The open circuit's voltage at the time of cell fabrication, is lower than 0.1 V permitting for extremely safe transportation and storage. Consequently, the device can be charged at the destination as battery or/and supercapacitor.

[0018] The galvanostatic charge/discharge cycles for the carbon(C)/electrolyte/sulfurbased(S) - device l@a are shown in Fig. 2, at a charging current of 25 mA, 15 mA/g_ceii and discharging at an open circuit. The EDLCs within device l@a begin to charge at Δν = 1.4 V and the EDLC mode is the only mode charged in all the curves in Fig. 2 and 3. This latter observation is reinforced by analyzing the device's discharge data; the device discharges to 0 V, not presenting any battery mode discharge. It is highlighted the high capacity and energy density that can be reached with device 1 shown in Fig. 4. The super capacitance exhibited: 2,230 F; 1,320 F/g_ceii and 44,800 F/g_carbon(-) (in the negative electrode) is another characteristic of these devices that will allow numerous practical applications.

[0019] In Fig. 5 and in the zoom in Fig. 6 the cell voltage reached is much higher and the device starts charging at 7.6 V, although it drops to 6 V subsequently to increase to 10 V afterwards. From 6-10 V the voltage increase tends to linearity. It is believed that in these cycles there is a battery mode charge/discharge corresponding to the overall stoichiometric electrochemical reaction

(-S₈ + 2NaC₆ Na₂ S + 2C₆) corresponding to a Gibbs energy of AG « -376 kJ/mol

8 >

discharge

(corresponding to a cell voltage of 1.95 V at 298 K) and a theoretical capacity of 372 mAh/g_carbon(- governed by the carbon electrode (NaC₆ < Na⁺ + e + C₆). It can be observed in all the discharge

discharges shown in Fig. 5 a hump after burst discharge that does not exceed 0.91 V. Although the expected battery mode discharging voltage is 1.95 V at 298 K. The value of x in Na_xC₆ < xNa⁺ + xe + C₆ corresponding to an overall reaction [-S₈ + 2Na_xC₆ < xNa₂ S + > 8 > discharge discharge

2C₆) and of the irreversibility percentage was previously described by (25).

[0020] Figure 7 shows charge/discharge cycles for device 2@a. In experiment a, after 20 cycles, this device shows a very similar behavior to device l@c, after 15 cycles. While the charging current for device l@c was 25 mA, 15mA/g, for device 2@a was 15 mA, 8mA/g. The discharge is essentially different. Device l@c shows a hump at 0.91 V, device 2@a shows a flat voltage after burst discharge that is observed at 2.46 V and that decreases to 0.91 V during the first cycle of the experiment. It is not very clear if there is a small hump at 0.91 V as in device l@c, but the first part of the discharge, after burst, seems to be due to the formation of the EDLCs, as will be subsequently explained.

[0021] Figure 8 shows the current explanation for the physical and chemical processes in the device during galvanostatic charge and discharge. In Fig. 8(1), at the carbon electrode and after the electron conduction and their accumulation at the surface, an EDLC(a) is formed with the separator electrolyte's Na-ions accumulating at the interface. This process leaves Na-ions holes (vacancies) on the opposite surface of the separator electrolyte (at the positive electrode interface), which correspond to a negative net charge. At the sulfurbased electrode, 46 wt% of the electrode is comprised of the sodium-rich electrolyte whose Na-ions accumulate at the surface. These Na-ion vacancies within the separator electrolyte, constitute the EDLC(b) at the positive electrode's interface. At the electrode/collector interface another EDLC(c) forms from the Na-ion vacancies on the sulfurbased electrode and the positive ions at the Al collector. Figure 2 presents charge curves that seem to be in agreement with the Fig. 8(1) charging process.

[0022] I n Fig. 8(2), the Na-ions of the electrolyte at the carbon electrode initiate diffusion into the electrode. The inbound ions within the carbon electrode will be reduced by the electrons and Na_xC6 will be formed. The carbon electrode, which is composed of amorphous carbon, determines the battery mode's maximum capacity has referred previously. The charge of the battery mode is not clear in the performed experiments since the EDLCs are always present during charge. However, the discharge data, indicates that battery charge took place within the Li-devices (26).

[0023] I n Fig. 8(3), it is presented an explanation for the device's discharge process. The electrolyte's Na-ions in the positive electrode EDLC(c) will receive the electrons transported via external circuit from the negative electrode which will reduce and react with sulfur, leaving vacancies at the inner surface of the positive electrode. A EDLC(b) will be formed at the sulfurbased electrode's interface with the Na-ions in the separator electrolyte and the vacancies of the electrode's electrolyte. On the negative electrode's side, oxidized carbon and/or the Na-ions that eventually remained after battery discharge will form another EDLC(a) with the Na-ions vacancies in the electrolyte (corresponding to a negative net charge). In Fig. 6, it is observed that once the EDLCs have burst discharged at Voc, the battery mode will begin discharging. I n Fig. 9 and 10, after burst discharge, the battery mode starts its discharge at «3 V and the device reaches a steady rate of 1.5 V after 12 or 21 hours of discharge. This second and long discharge mode is defined as the battery mode, it can include battery and additional EDLCs formations, as shown in Fig. 8(3).

[0024] I n Fig. 10 conversely to what it could observe with Li-devices (26), there is no visible Δν loss at discharge corresponding to the internal resistance. The resistance in Na-devices is usually an order of magnitude lower than in Li-devices (26).

[0025] The polarization inversion in Fig. 8(4) occurring during galvanostatic discharge at negative current is observed in a charge/discharge experiment with device 1, presented in Fig. 11.

[0026] It is highlighted the performance of the EDLC mode in device l@a. The supercapacitor mode of these devices can store more energy than any other known capacitor. For simplicity, it is consider the device to be in battery mode after the discharge burst although the EDLCs that charge in this mode contribute considerably to its discharge time, as previously discussed.

[0027] The present disclosure relates to devices that are safe, environmentally friendly and inexpensive. The present devices are both supercapacitors and batteries. The switching between the two modes on charge and discharge is autonomous. The EDLCs important discharge takes place in less than or in 1 second. It is likely that other EDLCs are formed at discharge which proportionate a delay of the battery mode discharge. Moreover, it was observed that it is possible to charge the devices during galvanostatic discharge. The present devices, working in battery mode, are uniquely charged/discharged from the Na present in the electrolyte; in effect, the sulfur at the positive electrode will only react with the Na-ions of the electrode's electrolyte protecting the electrodes interface and avoiding polysulfide shuttle. The Na-ions never cross this latter surface even during battery mode discharge. No substantial variation of the device's temperature was observed while running experiments (a maximum of 0.5 °C at 9V). The devices performed more than 30 cycles and sustained a shelf life of five months. It will be possible to tailor these devices by changing relative compositions, and by optimizing each component of the device. The capacitor or battery mode properties will depend on the previous parameters and therefore will be adapted in view of an application.

[0028] The present device is a combined EDLCs and carbon-sulfur (C-S) battery cell with a superionic sodium-rich doped Na₃CIO based glassy electrolyte. In order to properly characterize the cell, two identical devices for study under different testing conditions were fabricated. These devices' in their battery modes, are charged from the high sodium content in the solid electrolyte, the only material initially containing sodium ions. Each storage device is sequentially charged as an EDLC and battery and then finally as an EDLC. This order is reverted during discharge. It is an autonomous switching dual functioning device, which can present a device voltage of 9-10 V (once the supercapacitor is fully charged). In supercapacitor mode, one device has been measured as an EDLC with a power density of 3,636 W/cm³ (2.68xl0⁶ W/kg_ceii) for an energy density of 1.010 Wh/cm³ (746 Wh/kg_ceii), corresponding to a discharge time of approximately 1 s (burst C-rate = 3,168C for a discharge current of 2,788 A).

[0029] In an embodiment, the present disclosure relates to a supercapacitor and battery solid carbon-sulfur Na-ion based device with autonomous dual functionality and charged from the Na- rich glassy electrolyte.

[0030] The present disclosure relates to a layered electrochemical solid device comprising a positive electrode current collector, a positive electrode, a glass electrolyte, a negative electrode and a negative electrode current collector wherein

the positive electrode current collector comprises aluminium;

the positive electrode comprises sulfur, a glass electrolyte of formula Na₃-2_XM_xHalO or Na₃- 3_xMxHalO and carbon; the glass electrolyte composition comprising a compound of formula Na₃-2xM_xHalO or Na₃- 3_xM_xHalO wherein:

M is selected from the group consisting of boron, aluminium, magnesium, calcium, strontium, barium;

Hal is selected from the group consisting of fluoride, chloride, bromide, iodide or mixtures thereof;

X is the number of moles of M and 0 < x < 0.01;

the negative electrode comprises a carbonaceous material;

the negative electrode current collector comprises copper.

[0031] In an embodiment, said layered device electrochemical solid device comprises a positive electrode current collector, a positive electrode, a glass electrolyte, a negative electrode and a negative electrode current collector in which the collectors may additionally be electrodes being the copper the positive electrode and the aluminium the negative electrode.

[0032] In some cases, the collectors can have a predominant role. They can function as electrodes being the copper + carbon black the positive electrode and the sulfur + glass electrolyte + carbon in aluminum the negative electrode. This configuration makes the device works reversely to what was described for charge and discharge. In conclusion, when the role of the collectors is preponderant, they may overcome the role of the electrodes, reversing the functions of the electrodes and leading to a device with inverted electrodes.

[0033] In an embodiment, the positive electrode of the above-mentioned layered electrochemical device may comprise

3-80 % (w/w) of sulfur, in particular 30-50 % (w/w) of sulfur;

3-80 % (w/w) of the electrolyte composition described previously, in particular 30-50 % (w/w) and

less than 20% (w/w) of a carbon, in particular less than 10% (w/w) of a carbon.

[0034] In an embodiment for better results, X may be 0.002, 0.005, 0.007 or 0.01.

[0035] In an embodiment for better results, Hal may be mixture of chloride and iodide, or chloride and bromide, or fluoride and iodide.

[0036] In an embodiment Hal may be a mixture of chloride and iodide, in particular for better results Hal may be 0.5 CI + 0.5 I. [0037] In an embodiment for better results, said electrodes may be suitable to be charged with Na-ions from the electrolyte.

[0038] In an embodiment for better results, the carbonaceous material of the negative electrode of the layered electrochemical device may be selected from the group consisting of carbon black, graphite, graphene, carbon nanotubes, spongy carbon, carbon foam, carbon white, carbon composite, carbon paper, carbon fibres, carbon film, printed carbon, and mixtures thereof.

[0039] In an embodiment for better results, the aluminium of the positive electrode current collector of the layered electrochemical device may be selected from the following list: an aluminium foam, aluminium film, aluminium foil, aluminium composite, aluminium wires, aluminium surface, or mixtures thereof.

[0040] In an embodiment for better results, the copper of the negative electrode current collector of the layered electrochemical device may be selected from the following list: a copper foam, copper thin film, copper foil, copper composite, copper wires, copper surface, other engineered form of copper, or mixtures thereof.

[0041] In an embodiment for better results, the positive electrode may further comprise an alcohol, an organic solvent, a polymer, or mixtures thereof, preferably the alcohol may be ethanol, methanol, or mixtures thereof; more preferably the alcohol may be absolute methanol, absolute ethanol, or mixtures thereof.

[0042] In an embodiment for better results, the layered electrochemical device now disclosed may further comprise a confinement, protection or wrapping immersement, said confinement, protection or wrapping immersement may by a polymer or a resin. Preferably, said polymer may be a water-proof polymer, or a water-resistant polymer, or a flexible polymer, or a rigid polymer, or a non-flammable polymer; or said resin may be an epoxy resin.

[0043] The present disclosure also relates to a capacitor comprising the layered electrochemical solid device now disclosed and described.

[0044] Furthermore, the present disclosure also relates to a battery comprising the layered electrochemical solid device now described.

[0045] The present disclosure further relates to a dual mode battery comprising the layered electrochemical solid device.

[0046] Another aspect of the present disclosure further relates to an electrical actuator comprising the layered solid electrochemical device now described.

[0047] Another aspect of the present disclosure also relates to a sonar comprising the layered electrochemical solid device now described. [0048] Another aspect of the present disclosure also relates to a transducer comprising the layered electrochemical solid device now described.

[0049] Throughout the description and claims the word "comprise" and variations of the word, are not intended to exclude other technical features, additives, components, or steps. Additional objectives, advantages and features of the solution will become apparent to those skilled in the art upon examination of the description or may be learned by practice of the solution.

Brief Description of the Drawings

[0050] The following figures provide preferred embodiments for illustrating the description and should not be seen as limiting the scope of present disclosure.

[0051] Fig. 1: X-ray diffraction (XRD) patterns of the carbon black negative electrode showing amorphous carbon and graphite.

[0052] Fig. 2: Galvanostatic charge/discharge characterization cycles for device 1 during experiment a, which was performed after 10 galvanostatic charge/discharge cycles.

[0053] Fig. 3: Galvanostatic charge curve for device 1 during experiment a (the same of Fig. 1). This curve is the third charging curve shown in Fig. 1. The goal is to highlight capacity and energy density.

[0054] Fig. 4: Galvanostatic charge curve for device 1 during experiment a (the same of Fig. 1). This curve is the third charging curve shown in Fig. 1. The goal is to highlight the device's capacitance.

[0055] Fig. 5: Galvanostatic charge/discharge characterization cycles for device 1 during experiment c, which was performed after 15 galvanostatic charge/discharge cycles (including experiment a). In these experiments, for the same charging current of 25 mA, the voltage reaches 10 V. It can be observed a small hump after burst discharge that it is attributed to the battery mode discharge.

[0056] Fig. 6: Galvanostatic charge curve for device 1 during experiment c (the same of Fig. 4). This curve is the first charging curve shown in Fig. 4. The goal is to highlight the initial voltage, the initial voltage drop to 6 V and the small hump after burst discharge that it is attributed to the battery mode discharge even if it cannot clearly identify the battery mode charge.

[0057] Fig. 7: Galvanostatic charge/discharge characterization cycles for device 2 during experiment a, which was performed after 20 galvanostatic charge/discharge cycles. In these experiments, performed at a charging current of 15 mA, the voltage reaches approximately 10 V. It cannot be observed any hump after burst discharge eventually meaning that a new EDLC was formed, not letting the battery mode discharge.

[0058] Fig. 8: Simplified schematic representation of the processes occurring during galvanostatic charge/discharge of the present devices.

[0059] Fig. 9: Galvanostatic charge/discharge characterization cycles for device 2 during experiment b, which was performed after 24 cycles (including those in Fig. 6). In these experiments, performed at a charging current of 15 mA, the voltage reaches approximately 10 V. A hump cannot be observed after burst discharge meaning that a new EDLC was formed, not letting the battery mode discharge.

[0060] Fig. 10: Discharge burst characterization (I « 0 mA) for device 2 during experiment b, which was performed after 24 galvanostatic charge/discharge cycles (including those in Fig. 6). It cannot be observed a AV corresponding to the capacitor's mode internal resistance. (A) Discharge of the first cycle in Fig. 8. (B) Discharge of the second cycle in Fig. 8. (C) Discharge of the third cycle in Fig. 8.

[0061] Fig. 11 Initial galvanostatic charge/discharge cycles performed on device 1 (this experiment was performed before a). Evidence of polarization inversion and of charge while "discharging".

[0062] Fig. 12 Schematic representation of the equivalent circuit after open circuit's discharge correspondent to Fig. 7(3). R_n = 2R_e + Ri.

Detailed description

[0063] The materials and methods are now disclosed.

[0064] In an embodiment, the synthesis of Na3-2*o.oo5Bao.oosCIO of was performed as follows: the glassy electrolyte was prepared from the commercial precursors (Panreac > 99.9 % for analysis), NaOH (Merck > 99 %) and Ba(OH)₂.8H₂0 (Merck 98.5%) as described in [23,27]. After synthesis the electrolyte was heated to 100-300 °C for one hour and then cooled down, avoiding contamination with water from the air's moisture. A slurry was then prepared by grinding the electrolyte in ethanol (Merck 99.9% absolute for analysis).

[0065] In an embodiment, the preparation of the electrodes was performed as follows: the positive electrodes were prepared by adding sulfur, Ss, (Alfa Aesar Powder 99.9995% Puratronic) to the above prepared electrolyte (before mixing it with ethanol) and to carbon black (TIMCAL super C65) in a 47:46:7 weight ratio. The carbon black's XRD (Fig. 1) shows the presence of graphite and amorphous carbon, probably denoting grains with an external crystalline layer and an amorphous inner phase [28]. This mixture was grinded in ethanol (Merck 99.9% absolute for analysis). There were no prior perceptible reactions between the sulfur, the electrolyte and the graphite as presented in the XRD but the electrolyte could have reacted partially and form an amorphous phase that could not be distinguished from the amorphous electrolyte and carbon . The slurry was deposited on an Aluminum (Al) collector foil (Alfa Aesar Foil 99.45% 0.025 mm thick) with 2.50x2.50 cm² or 2.50x3.45 cm² and let dry at approximately 50-150 °C for 30 min, in particular corresponding to 40-80 mg/cm² of positive electrode. The electrolyte's slurry was deposited on the top of the positive electrode and let dry for approximately 50-150 °C for 30 min, in particular corresponding to 100-300 mg/cm² of electrolyte. The negative electrode was prepared by mixing carbon black from TIMCAL super C65 with ethanol (Merck 99.9% absolute for analysis) in a 12:88 weight ratio. The resulting slurry was deposited on a copper (Cu) collector foil (Alfa Aesar Foil 99.8% 0.025 mm thick) and let dry for about 10-20 min at 50-150 °C, in particular corresponding to 8-14 mg/cm² of carbon. The device is then prepared by matching the two collectors resulting in a layered device with Al collector/positive electrode/electrolyte/negative electrode/Cu collector. The resulting active devices were 0.15-0.35 cm thick. The device was then hermetically sealed in a moisture and oxygen free container. Collectors' terminals were left with external access.

[0066] In an embodiment, X-ray diffraction measurements were made. Samples of the positive and negative electrodes and electrolyte were submitted to X-ray Diffraction (XRD) in a Panalytical instrument, using CuKa radiation (Λ = 1.54 A) with 0.2° 2ϋ steps and 0.5 s dwelling time, to determine the amount of the product present in the sample.

[0067] In an embodiment, electrochemical measurements were made. Galvanostatic cycling, cyclic voltammetry (CV), and electrochemical impedance spectroscopy (EIS) were performed using a SP240 potentiostat (Bio-Logic, France). Galvanostatic cycling was performed at 0.2-1.8 mA/g and between the potential limits of -10 V to 10 V versus Na/Na⁺ and Na⁺/Na. The CV was performed using scan rates that ranged from 1 mV/s to 500 mV/s. The EIS was performed at open circuit voltage, with a sinus amplitude of 10 mV, and frequencies that ranged from 100 mHz to 5 MHz.

[0068] In an embodiment, open circuit voltages (at fabrication, with battery mode charged and after discharge) were additionally measured with commercial multimeters.

[0069] In an embodiment, conductivity, resistance and permittivity calculations were made. The ionic conductivity, resistance and permittivity of the crystalline and glassy electrolyte may be measured using gold block electrodes and calculated using the equivalent circuits described in [23]. [0070] In an embodiment, for the devices, the equivalent circuit in Fig. 12 should be a reasonable model for three double layer capacitors (with capacitances C_c - EDLC at the interface of carbon electrode and C_s - EDLC at the interface of the sulfurbased electrode and C_SCoi - EDLC inner sulfurbased electrode and aluminum collector) in parallel with their charge transfer resistance (R_c Rs and Rscoi respectively) and three additional resistances in serial (Rn = 2R_e+Ri) corresponding to the ohmic drop at the electrodes and electrolyte.

[0071] In an embodiment, the Laplace transform was chosen for the study of the equivalent circuit in Fig. 12, characterized by its transfer function. In this case the impedance, Z(s), of a dipole is the

£{AV(t)} _ AV(s)

transfer function for the current input Z(s) = with AV = V(t) - 1 (0) and Δ/ =

£{A/(t)} ~~ A/(s)

/(t)— /(0). A galvanostatic charge corresponds to a Heaviside step function response which is 0 for t < 0 and 1 for t > 0. The Laplace transform of a Heaviside step function current is given by

A/(s) = £{<5/(t)} =— . The Z_eq(s), for the circuit in Fig. 12, is: eq — sR_cC_c+l + sR_sC_s+l + ^RScol

(3)

sRscolCscol + 1

V(s) ^J = Z_eQl{s) = - s (R_a " +— SR_C^C_C—+1 +— SR_S^C_S—+1 + sR_Sc—_olC_Scol + l ) (4)

V(t) = L-¹ \- {R_a +—^- +—^- + R_C ( 1 - e

l s \ ¹¹ SR_CC_C+1 SR_SC_S+1 sR_Sc ^ta _oiC_Scoi+l )J] J = 5IR_a + 5I ^'wA / +

5IR_S (l - e^"%¾) + SIRscoi (l - e~^Rscoic_Sco j (5)

[0072] The equivalent impedance (3) is used to analyze the Cole-Cole diagram and determine the Nyquist impedance resulting from EIS.

[0073] In this case, the resulting Cole-Cole diagrams would be two perfect semi-circles. However, for real systems, sometimes this is not the case. A constant phase element (CPE), Q, is then used, instead of the capacitance C. The resulting Cole-Cole diagram corresponds to a depressed semicircle in its upper-part. The analogy between Q and C is obtained using the following equation which gives the capacitance value at the frequency corresponding to the apex of the Cole-Cole diagram.

CEDLC = <2(ω_c)^α-¹ (6)

where ω_ε = l/(i?C)^_1/^a (at the top of the semi-circle). The pseudo-capacitance of each EDLC is then computed.

[0074] In an embodiment, considering the association of capacitors without having into account their charge transfer resistance it can calculate the equivalent capacitance. Since the capacitors are associated in serial, its equivalent capacitance is C_ea = C_cC_sC_Scoi/(C_cC_s + C_cC_Scoi + C_sC_Scoi) . If the capacitances are similar, then C_ea « C/3. The capacitance of each EDLC can be written:

CEDLC ⁼ ~~[~ (?)

where ε is the permittivity at zero-frequency (ε = ε_τε₀ where e_r is the zero-frequency relative permittivity and ε₀ is the vacuum permittivity, ε₀ = 8.854^χ10^~12 F/m. A is the plates' surface area and d the spacing between the plates of the capacitor (the Li-ion radius or 2xLi-ion radius, depending on the EDLC).

[0075] I n an embodiment, capacitance, internal resistance, energy, power and C-rate calculations were made. The capacitance determined from the CV data is given by:

C = J (8)

AV ^J v '

The energy determined from the CV data is given by:

E = AV j— (9)

where C is the capacitance in Farad (F), / is the current in (A), v is the rate in (V/s), V is the voltage in (V), Δ\/ is the voltage window in (V), t is time in (s) and E is the energy in (J).

[0076] The capacitance determined from the galvanostatic charge/discharge data is given by:

C = Q X 3,600 / ' charge I discharge (1°)

where C is the capacitance in (F), Q is the capacity in (Ah), / is the current in (A), V is the voltage in (V), and t is time in (s). Calculations of the gravimetric capacitance in (F/g) and (F/cm³) were also performed.

[0077] I n an embodiment, the internal resistance of the EDLCs and electrolyte were estimated from the voltage drop (Δν = IRdmp) divided by the total variation in the applied current (lcharge- Idischarge) using the following equation:

Ri = ^ (11)

^charge ^discharge

[0078] For example, if lcharge = 2.4 mA and I discharge = -2.4 mA, I charge- 1 discharge = 2x2.4 mA.

[0079] The energy of the device was calculated using the following equation:

E = f VdQ (12)

where E is the energy in (J), V is the voltage in (V) and Q is the capacity in (C). The energy can be given in (Wh) if the capacity is given in (Ah). The energy density is in which the Volume is

Volume

given in cm³. [0080] The energy of a device's capacitor was additionally calculated using the following equation: E = (13)

2 3,600 * '

where E is the energy in (Wh or AVh), C is the capacitance in (F) and AV is the discharge voltage range in (V). The energy density is in which the Volume is given in cm³.

Volume

[0081] The power density of the device was calculated from the formula given in equation: P =— X 3,600 (14)

At '

where P is the power density in (W/cm³), E is the volumetric energy density in (Wh/cm³) obtained from equation (12) and At is the discharge time, in particular in seconds.

[0082] In an embodiment, Charge rate or discharge was expressed as a function of the experimental capacity and calculated from the formula given in the following equation:

c

- charge /discharge rate = C (experimental capacity in Ah) /n(number of hours) (15)

[0083] For example, a device with a capacity of 100 mAh will be charged at a 0.024C rate, if the current charge value is 2.4 mA which corresponds to 41.7 h (charging hours).

[0084] The disclosure should not be seen in any way restricted to the embodiments described and a person with ordinary skill in the art will foresee many possibilities to modifications thereof.

[0085] The above described embodiments are combinable. The following claims further set out particular embodiments of the disclosure.

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Claims

C L A I M S

1. A layered electrochemical solid device comprising a positive electrode current collector, a positive electrode, a glass electrolyte, a negative electrode and a negative electrode current collector wherein

the positive electrode current collector comprises aluminium;

the positive electrode comprises sulfur, a glass electrolyte of formula Na3-2xM_xHalO or Na3-3xM_xHalO and carbon;

the glass electrolyte composition comprising a compound of formula Na3-2xM_xHalO or Na3-3xM_xHalO wherein:

M is selected from the group consisting of boron, aluminium, magnesium, calcium, strontium, barium;

Hal is selected from the group consisting of fluoride, chloride, bromide, iodide or mixtures thereof; X is the number of moles of M and 0 < x < 0.01;

the negative electrode comprises a carbonaceous material;

the negative electrode current collector comprises copper.

2. The layered electrochemical device according to any of the previous claim wherein the positive electrode comprises 3-80 % (w/w) of sulfur, and 3-80 % (w/w) of the electrolyte composition described in any one of the previous claims and less than 20% (w/w) of a carbon; in particular less than 10% (w/w).

3. The layered electrochemical device according to any of the previous claim wherein the positive electrode comprises 30-50 % (w/w) of sulfur, and 30-50 % (w/w) of the electrolyte composition described in any one of the previous claims and less than 20% (w/w) of a carbon, in particular 10% of carbon.

4. The layered electrochemical device according to any of the previous claims wherein X is 0.002, 0.005, 0.007 or 0.01.

5. The layered electrochemical device according to any of the previous claims wherein Hal is a mixture of chloride and iodide, or chloride and bromide, or fluoride and iodide.

6. The layered electrochemical device according to any of the previous claims wherein Hal is Hal = 0.5CI + 0.51.

7. The layered electrochemical device according to any of the previous claims wherein the electrodes are suitable to be charged with Na-ions from the electrolyte.

8. The layered electrochemical device according to the previous claims wherein the carbonaceous material of the negative electrode is selected from the group consisting of carbon black, graphite, graphene, carbon nanotubes, spongy carbon, carbon foam, carbon white, carbon composite, carbon paper, carbon fibres, carbon film, printed carbon, and mixtures thereof.

9. The layered electrochemical device according to any of the previous claims wherein the aluminium of the positive electrode current collector is selected from: an aluminium foam, aluminium film, aluminium foil, aluminium composite, aluminium wires, aluminium surface, or mixtures thereof.

10. The layered electrochemical device according to any of the previous claims wherein the copper of the negative electrode current collector is selected from : a copper foam, copper thin film, copper foil, copper composite, copper wires, copper surface, or mixtures thereof.

11. The layered electrochemical device according to any of the previous claims wherein the positive electrode further comprises an alcohol, an organic solvent, a polymer, or mixtures thereof.

12. The layered electrochemical device according to the previous claim wherein the alcohol is ethanol, methanol, or mixtures thereof; preferably absolute methanol, absolute ethanol, or mixtures thereof.

13. The layered electrochemical device according to any of the previous claims wherein said device further comprises a confinement, protection or wrapping immersement.

14. The layered electrochemical device according to the previous claim wherein the confinement, protection or wrapping immersement is by a polymer or a resin.

15. The layered electrochemical device according to the previous claim wherein the resin is an epoxy or the polymer is a water-proof polymer, or a water-resistant polymer, or a flexible polymer, or a rigid polymer, or a non-flammable polymer.

16. A capacitor comprising the layered electrochemical solid device described in any one of the previous claims.

17. A battery comprising the layered electrochemical solid device described in any one of the previous claims.

18. A dual mode battery comprising the layered electrochemical solid device described in any one of the previous claims.

19. An electrical actuator comprising the layered solid electrochemical device described in any one of the previous claims.

20. A sonar comprising the layered electrochemical solid device described in any one of the previous claims.

21. A transducer comprising the layered electrochemical solid device described in any one of the previous claims.