A separator which is permeable to hydroxide ion, and which contains at least one Dendrite Stopping Substance such as Ni(OH).sub.2, or its precursor.

An electrolyte for use in an energy storage apparatus includes: a metal halide-based electrolytic solution arranged to electrically connect a cathode and an anode of the energy storage apparatus during an operation of charging and discharging cycle. The electrolytic solution includes a first metal halide arranged to prevent a dissolution of the cathode and/or a formation of dendrites on the anode during the operation of charging and discharging cycle, thereby maintaining cyclic stability of the energy storage apparatus.

An electrolyte for use in an energy storage apparatus includes: a metal halide-based electrolytic solution arranged to electrically connect a cathode and an anode of the energy storage apparatus during an operation of charging and discharging cycle. The electrolytic solution includes a first metal halide arranged to prevent a dissolution of the cathode and/or a formation of dendrites on the anode during the operation of charging and discharging cycle, thereby maintaining cyclic stability of the energy storage apparatus.

The present disclosure relates to a battery system with adjustable heating rate and control method thereof, the battery system comprises a battery pack, a heating plate, a power control module, and a battery management system; when the temperature of the battery pack is lower than the preset self-heating switch-on temperature, the power control module is turned on, and the battery management system transmits the collected status information of the battery pack to the power control module, the power control module adjusting the current on-off time and switching frequency of the heating plate through a PWM signal to adjust the heating power and heating rate, to realize self-heating of the battery; when the temperature of the battery pack reaches the preset self-heating switch-off temperature, the power control module is turned off to stop heating; wherein, the power control module further includes a current adjustment module, a current acquisition module, and a heating control module. The present disclosure can realize the beneficial effects of fast heating rate, long driving range, and fast charging at low temperature of the power battery system.

Electrolyte formulations including a high salt concentration. The electrolyte formulation includes an organic solvent and a lithium salt, wherein the lithium salt is mixed with the organic solvent at a concentration of at least 20 Mole %, or at least 40 Mole %, or at least 50 Mole %. The organic solvent includes N-methyl-2-pyrrolidone, butylene carbonate, butyl propionate, pentyl acetate, γ-caprolactone, propylene glycol sulfite, ethyl methyl sulfone, butyl sulfoxide or combinations thereof. The lithium salt includes lithium bis(trifluoromethane sulfonyl) imide, lithium tetrafluoroborate, or lithium hexafluorophosphate.

An alkaline secondary battery disclosed in the present application includes a positive electrode containing a positive electrode active material, a negative electrode, and a separator. The positive electrode active material contains a mixture of a silver oxide and a silver-bismuth complex oxide. A discharge curve is obtained when the battery that is fully charged is discharged with a constant current until a battery voltage drops to 1.0 V. The battery voltage at a point on the discharge curve where x (%) of a total discharge capacity has been discharged from the battery since start of discharge is represented by V.sub.x (V). The discharge curve satisfies V.sub.10−V.sub.70≤0.08, has a step in the range of 70≤x≤90, and shows that a size of the step represented by V.sub.70−V.sub.90 is 0.04 or more and 0.15 or less.

An alkaline secondary battery disclosed in the present application includes a positive electrode containing a positive electrode active material, a negative electrode, and a separator. The positive electrode active material contains a mixture of a silver oxide and a silver-bismuth complex oxide. A discharge curve is obtained when the battery that is fully charged is discharged with a constant current until a battery voltage drops to 1.0 V. The battery voltage at a point on the discharge curve where x (%) of a total discharge capacity has been discharged from the battery since start of discharge is represented by V.sub.x (V). The discharge curve satisfies V.sub.10−V.sub.70≤0.08, has a step in the range of 70≤x≤90, and shows that a size of the step represented by V.sub.70−V.sub.90 is 0.04 or more and 0.15 or less.

An electrolyte for use in an energy storage apparatus includes: a metal halide-based electrolytic solution arranged to electrically connect a cathode and an anode of the energy storage apparatus during an operation of charging and discharging cycle. The electrolytic solution includes a first metal halide arranged to prevent a dissolution of the cathode and/or a formation of dendrites on the anode during the operation of charging and discharging cycle, thereby maintaining cyclic stability of the energy storage apparatus.

An alkaline secondary battery disclosed in the present application includes: a positive electrode that is provided with a positive electrode mixture layer containing a silver oxide; a negative electrode; and an alkaline electrolyte. The positive electrode mixture layer further contains insulating inorganic particles and carbon particles. The carbon particles include graphite particles and carbon black particles. The negative electrode contains zinc-based particles selected from zinc particles and zinc alloy particles. The alkaline electrolyte contains potassium hydroxide or sodium hydroxide, and lithium hydroxide, and polyalkylene glycols. Further, in a charging method and a charging device for an alkaline secondary battery disclosed in the present application, a charging voltage during constant-voltage charging is set so that in the positive electrode, an oxidation reaction from silver to silver oxide (I) progresses while an oxidation reaction from silver oxide (I) to silver oxide (II) does not progress.

A system and method for mitigating the effects of a thermal event within a non-metal-air battery pack is provided in which the hot gas and material generated during the event is directed into the metal-air cells of a metal-air battery pack. The metal-air cells provide a large thermal mass for absorbing at least a portion of the thermal energy generated during the event before it is released to the ambient environment. As a result, the risks to vehicle passengers, bystanders, first responders and property are limited.