Negative thermal expansion based protective mechanisms for battery cells

What is claimed is: 1 . A battery cell, comprising: a first electrode coupled with a first current collector; a second electrode coupled with a second current collector; a separator interposed between the first electrode and the second electrode; and a negative thermal expansion (NTE) current interrupter including a pyrophosphate, the negative thermal expansion (NTE) current interrupter contracting in response to a temperature trigger to form a nonconductive gap that disrupts a current flow within the battery cell. 2 . The battery cell of claim 1 , wherein the negative thermal expansion (NTE) current interrupter is interposed between the first electrode and the first current collector, and wherein the contracting of the negative thermal expansion (NTE) current interrupter forms the nonconductive gap between the first electrode and the first current collector. 3 . The battery cell of claim 1 , wherein the negative thermal expansion (NTE) current interrupter is interposed between the separator and at least one of the first electrode and the second electrode, and wherein the contracting of the negative thermal expansion (NTE) current interrupter forms the nonconductive gap between the separator and the at least one of the first electrode and the second electrode. 4 . The battery cell of claim 1 , further comprising: a safe layer disposed on a surface of the negative thermal expansion (NTE) current interrupter, the safe layer causing a delamination in response to one or more of the temperature trigger, a voltage trigger, and a current trigger. 5 . The battery cell of claim 4 , wherein the safe layer causes the delamination by at least one of (i) decomposing, (ii) generating a gas, and (iii) generating a liquid that vaporizes to form the gas. 6 . The battery cell of claim 4 , wherein the delamination includes at least one of (i) a separation of the safe layer into one or more separate layers and (ii) a separation of the safe layer from the negative thermal expansion (NTE) current interrupter. 7 . The battery cell of claim 4 , wherein the delamination forms one or more additional nonconductive gaps that disrupt the current flow within the battery cell. 8 . The battery cell of claim 4 , wherein the delamination increases the nonconductive gap formed by the contracting of the negative thermal expansion (NTE) current interrupter along one or more dimensions. 9 . The battery cell of claim 1 , wherein the contracting of the negative thermal expansion (NTE) current interrupter includes a decrease in a size of the negative thermal expansion (NTE) current interrupter along one or more dimensions. 10 . The battery cell of claim 1 , wherein the contracting of the negative thermal expansion (NTE) current interrupter is isotropic or anisotropic. 11 . The battery cell of claim 1 , wherein the pyrophosphate is a metal pyrophosphate. 12 . The battery cell of claim 1 , wherein the pyrophosphate is a copper pyrophosphate (CPO). 13 . The battery cell of claim 1 , wherein the negative thermal expansion (NTE) current interrupter includes the pyrophosphate, polyvinylidene fluoride (PVDF), and carbon black dissolved in an N-methyl pyrrolidone (NMP) solvent. 14 . The battery cell of claim 1 , wherein the pyrophosphate is a pyrophosphate powder with particles that are less than 1-micron in size. 15 . The battery cell of claim 1 , wherein the pyrophosphate (CPO) is 16 . The battery cell of claim 1 , wherein the battery cell is a metal ion battery cell. 17 . The battery cell of claim 1 , wherein the battery cell is a cylindrical cell, a prismatic cell, a pouch cell, or a button cell. 18 . The battery cell of claim 1 , wherein the first electrode is a positive electrode and the second electrode is a negative electrode. 19 . The battery cell is claim 1 , wherein the first electrode includes a lithium metal oxide and the second electrode includes graphite. 20 . The battery cell of claim 1 , wherein the battery cell is thermally conditioned at 70° C. for two hours.