Rechargeable battery with voltage activated current interrupter

What is claimed is: 1 . A high energy density rechargeable (HEDR) metal-ion battery comprising: an anode energy layer; a cathode energy layer; a separator for separating the anode energy layer from the cathode energy layer; an anode current collector for transferring electrons to and from the anode energy layer, the high energy density rechargeable metal-ion battery being rechargeable and characterized by a maximum safe voltage for avoiding overcharge; and an interrupt layer activatable for interrupting current within the high energy density rechargeable battery upon exposure to voltage in excess of the maximum safe voltage, the interrupt layer sandwiched between the cathode energy layer and the cathode current collector, the interrupt layer, when unactivated, being laminated to the anode current collector for conducting current therethrough, the interrupt layer, when activated, being delaminated from the anode current collector for interrupting current therethrough, the interrupt layer including a voltage sensitive decomposable component for decomposing upon exposure to voltage in excess of the maximum safe voltage, the voltage sensitive decomposable component for evolving a gas upon decomposition, the evolved gas for delaminating the interrupt layer from the anode current collector for interrupting current therethrough, whereby the high energy density rechargeable metal-ion battery avoids overcharge by activation of the interrupt layer upon exposure to voltage in excess of the maximum safe voltage for interrupting current therethough. 2 . The high energy density rechargeable metal-ion battery cell of claim 1 wherein the interrupt layer is porous and has a composition comprising: a ceramic powder defining an interstitial space; a binder for partially filling the interstitial space for binding the ceramic powder; and a conductive component dispersed within the binder for imparting conductivity to the interrupt layer, the interstitial space remaining partially unfilled for imparting porosity and permeability to the interrupt layer. 3 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer is compacted for reducing the unfilled interstitial space and increasing the binding of the ceramic powder by the binder. 4 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer comprises greater than 30% ceramic powder by weight. 5 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer comprises greater than 50% ceramic powder by weight. 6 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer comprises greater than 70% ceramic powder by weight. 7 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer comprises greater than 75% ceramic powder by weight. 8 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer comprises greater than 80% ceramic powder by weight. 9 . The high energy density rechargeable metal-ion battery cell of claim 2 wherein the interrupt layer is permeable for transporting ionic charge carriers. 10 . The high energy density rechargeable metal-ion battery cell of claim 1 wherein the interrupt layer is non-porous and has a composition comprising: a non-conductive filler; a binder for binding the non-conductive filler; and a conductive component dispersed within the binder for imparting conductivity to the interrupt layer. 11 . The high energy density rechargeable metal-ion battery cell of claim 10 wherein the interrupt layer is impermeable to transport of ionic charge carriers. 12 . The high energy density rechargeable metal-ion battery cell of claim 1 wherein the interrupt layer is sacrificial at voltages above the maximum safe voltage for recharging. 13 . The high energy density rechargeable metal-ion battery cell of claim 12 wherein the interrupt layer including a ceramic powder that chemically decomposes above maximum safe voltage for evolving the gas. 14 . The high energy density rechargeable metal-ion battery cell of claim 13 wherein the gas is fire retardant. 15 . A method for interrupting a recharging process for a high energy density rechargeable metal-ion battery upon exposure to voltage at or above a maximum safe voltage for avoiding overcharge, the high energy density rechargeable metal-ion battery comprising an anode energy layer, a cathode energy layer, a separator between the anode energy layer and the cathode energy layer, and an anode current collector for transferring electrons to and from the anode energy layer, the method comprising: overcharging the high energy density rechargeable metal-ion battery for increasing the voltage above the maximum safe voltage for recharging; and interrupting the overcharging by evolving a gas by decomposition of a voltage sensitive decomposable component within a interrupt layer laminated to the anode current collector, the evolved gas delaminating the interrupt layer from the anode current collector, whereby the overcharging of the high energy density rechargeable metal-ion battery is interrupted by evolution of gas within the interrupt layer for delaminating the interrupt layer from the anode current collector.