Abstract: A method for assessing a state of charge/discharge (SOC/SOD) for a secondary electrochemical cell, the cell having a first operational mode during which the cell is charged from a power supply connected to terminals of the cell, a second operational mode during which the cell is discharged into a load and a rest mode, the method comprising steps of measuring entropy and enthalpy for the electrochemical cell in the course of the first and second operational modes and during rest, and calculating a data representative of the state of charge/discharge (SOC/SOD).

Abstract: A Non-Linear Voltammetry (NLV)-based method for charging batteries. It also relates to a fast charging system implementing this method. Adaptive charging, Non-Linear Voltage changing, and Relaxation are the key cornerstones of this method. Adaptive charging allows the system to balance the charging based on the user's time requirements, required charge capacity and the SOC and SOH of the battery. Non-linearly changing the voltage coupled with a suitable relaxation pattern allows this method to gain the maximum charge capacity without straining the battery.

Abstract: A method for fast charging a battery cell provided with charge/discharge terminals to which a charging voltage can be applied with a flowing charging current, the method comprising the steps of: applying to terminals of the battery cell a plurality of constant voltage stages Vj, where Vj+1>Vj, j=1, 2 . . . , k, each voltage stage comprising intermittent nj voltage plateaus, between two successive voltage plateaus within a voltage stage, letting the charging current going to rest for a rest period, Rjp, 1?p?nj, the fast-charging method proceeding until either one of the following conditions is reached: a pre-set charge capacity or state of charge is reached, the cell temperature exceeds a pre-set limit value Tlim and the cell voltage has exceeded a pre-set limit value Vlim.

Abstract: A Non-Linear Voltammetry (NLV)-based method for charging batteries. It also relates to a fast charging system implementing this method. Adaptive charging, Non-Linear Voltage changing, and Relaxation are the key cornerstones of this method. Adaptive charging allows the system to balance the charging based on the user's time requirements, required charge capacity and the SOC and SOFT of the battery. Non-linearly changing the voltage coupled with a suitable relaxation pattern allows this method to gain the maximum charge capacity without straining the battery.

Abstract: A method is used for increasing the discharge capacity (Qdisch) of a battery cell provided with charge/discharge terminals to which a charging voltage can be applied with a flowing charging current. The method involves applying a plurality of charge cycles to the battery cell, each of which comprises applying a plurality of constant voltage stages each comprising intermittent voltage plateaus, and monitoring current flow. The temperature of the battery cell is monitored and maintained under a predetermined limit temperature, and the charge cycles are performed until the discharge capacity reaches a predetermined target capacity greater than the rated capacity.

Abstract: An adaptive charging protocol (ACP) implemented for fast-charging a rechargeable battery having electrode terminals connected to terminals of a power supply provided to apply time-varying voltages to the electrodes, comprising, before starting a charging operation for the battery, the steps of: detecting the existence of historical data on previous charging operations for the battery; in case of detection, processing the historical data to adjust charging parameters in view of optimizing the charging operation; in absence of detection, electrically testing the battery to get data on variations of the state of charge (SOC) for the battery, in view of building a learning model on the SOC variations to be used for optimizing the charging operation.

Abstract: A method for online assessing a state of health (SOH) of an electrochemical cell, comprises a step for estimating the state of health (SOH) of the electrochemical cell from thermodynamics data related to the cell the thermodynamics data including entropy and enthalpy variations ?S, ?H within the cell. A system for fast-charging a rechargeable battery with terminals connected to internal electrochemical cells, comprises a power supply connected to the rechargeable battery and arranged for applying a time-varying charging voltage to the battery terminals, a charging-control processor for controlling the power supply, and a system for online assessing a state of health (SOH) of the battery, the SOH assessment system comprising means for estimating the state of health (SOH) of the electrochemical cell from thermodynamics data related to the battery.

Abstract: A method for fast-charging an electrochemical cell comprises the steps of: —providing the electrochemical cell, the electrochemical cell presenting an initial state of charge (SOC), and—providing a time-varying charging voltage to the electrochemical cell, thereby generating a charging current resulting in charging of the electrochemical cell from the initial SOC up to a target value SOCf for the state of charge. The step of providing a time-varying charging voltage involves applying N bundles of current pulses in such a way that: each bundle k (1?k?N) comprises a variable number Pk of ik pulses (1?ik?Pk), each ik pulse in a k bundle being defined by a C-rate equal to ni,k·C and a duration ?i,k. at each pulse ik, the state of charge (SOC) is increased by ?ik (%)=ni,k·?i,k/M, with M as a predetermined parameter.

Abstract: A method for detecting internal short circuit within an electrochemical cell, from on-line measuring and processing thermodynamics data and kinetics data on the electrochemical cell. The thermodynamics data comprises open-circuit voltage data, entropy variations and/or enthalpy variations data, and combinations thereof. The kinetics data comprises cell voltage, cell temperature, cell internal resistance and current, and combinations thereof.

Abstract: A Non-Linear Voltammetry (NLV)-based method for charging batteries. It also relates to a fast charging system implementing this method. Adaptive charging, Non-Linear Voltage changing, and Relaxation are the key cornerstones of this method. Adaptive charging allows the system to balance the charging based on the user's time requirements, required charge capacity and the SOC and SOFT of the battery. Non-linearly changing the voltage coupled with a suitable relaxation pattern allows this method to gain the maximum charge capacity without straining the battery.

Abstract: An adaptive charging protocol (ACP) implemented for fast-charging a rechargeable battery having electrode terminals connected to terminals of a power supply provided to apply time-varying voltages to the electrodes, comprising, before starting a charging operation for the battery, the steps of: detecting the existence of historical data on previous charging operations for the battery, in case of detection, processing the historical data to adjust charging parameters in view of optimizing the charging operation; in absence of detection, electrically testing the battery to get data on variations of the state of charge (SOC) for the battery, in view of building a learning model on the SOC variations to be used for optimizing the charging operation.

Abstract: A method for fast-charging an electrochemical cell comprises the steps of: —providing the electrochemical cell, the electrochemical cell presenting an initial state of charge (SOC), and—providing a time-varying charging voltage to the electrochemical cell, thereby generating a charging current resulting in charging of the electrochemical cell from the initial SOC up to a target value SOCf for the state of charge. The step of providing a time-varying charging voltage involves applying N bundles of current pulses in such a way that: each bundle k (l?k?N) comprises a variable number Pk of ik pulses (l?ik?Pk), each ik pulse in a k bundle being defined by a C-rate equal to ni,k·C and a duration ?i,k. at each pulse ik, the state of charge (SOC) is increased by ?ik (%)=ni,k·?i,k/M, with M as a predetermined parameter.

Abstract: A method for online assessing a state of health (SOH) of an electrochemical cell, comprises a step for estimating the state of health (SOH) of the electrochemical cell from thermodynamics data related to the cell, the thermodynamics data including entropy and enthalpy variations ?S, ?H within the cell. A system for fast-charging a rechargeable battery with terminals connected to internal electrochemical cells, comprises a power supply connected to the rechargeable battery and arranged for applying a time-varying charging voltage to the battery terminals, a charging-control processor for controlling the power supply, and a system for online assessing a state of health (SOH) of the battery, the SOH assessment system comprising means for estimating the state of health (SOH) of the electrochemical cell from thermodynamics data related to the battery.

Abstract: A method for assessing a state of charge/discharge (SOC/SOD) for a secondary electrochemical cell, the cell having a first operational mode during which the cell is charged from a power supply connected to terminals of the cell, a second operational mode during which the cell is discharged into a load and a rest mode, the method comprising steps of measuring entropy and enthalpy for the electrochemical cell in the course of the first and second operational modes and during rest, and calculating a data representative of the state of charge/discharge (SOC/SOD).

Abstract: Provided are methods, systems and devices for thermodynamically evaluating electrochemical systems and components thereof, including electrochemical cells such as batteries. The present systems and methods are capable of monitoring selected electrochemical cell conditions, such as temperature, open circuit voltage and/or composition, and carrying out measurements of a number of cell parameters, including open circuit voltage, time and temperature, with accuracies large enough to allow for precise determination of thermodynamic state functions and materials properties relating to the composition, phase, states of charge, health and safety and electrochemical properties of electrodes and electrolytes in an electrochemical cell. Thermodynamic measurement systems of the present invention are highly versatile and provide information for predicting a wide range of performance attributes for virtually any electrochemical system having an electrode pair.

Abstract: The invention relates to a metal battery, and in particular, to a metal battery including a liquid anode and a liquid cathode. The metal batteries can operate at ambient temperature and can be prepared fully uncharged for safe transport and storage.

Abstract: According to embodiments of the present invention, an electrode is provided. The electrode includes silicon, tin, and a non-alloy of a transition metal. According to further embodiments of the present invention, a battery cell including the electrode and a battery arrangement having a plurality of battery cells are also provided. Methods of forming the electrode, the battery cell and the battery arrangement are also provided.

Abstract: The invention relates to an electrolyte for a metal air battery, and in particular, to an ionic liquid electrolyte for a metal air battery. The ionic liquid electrolyte includes an additive to improve oxygen solubility thereof. The invention also define a method of impregnating a fluorinated carbon compound into an electrode comprising depositing onto the electrode a dispersion comprising the fluorinated carbon compound dissolved in an organic solvent and placing the electrode in an inert environment.

Abstract: A method for testing a battery may be provided. The method may include: bringing the battery to a pre-determined voltage; determining a parameter of the battery, the parameter of the battery including at least one of an entropy of the battery at the pre-determined voltage or an enthalpy of the battery at the pre-determined voltage; and determining an ageing history of the battery based on the determined parameter.

Abstract: The invention relates to an electrolyte membrane for a liquid anode cell battery. In particular, the electrolyte membrane is coated with a coating protective against decomposition of the electrolyte membrane in contact with a liquid anode.