Induction heater for calendar roller

What is claimed is: 1 . A roller system for forming a material layer on a substrate, the roller system comprising: an inductive power generator to generate a magnetic field; an opposing member; and a roller proximal to the opposing member, wherein the roller and the opposing member are configured to press the material layer on the substrate interposed therebetween, the roller including: a heater plate thermally coupled to the roller, the heater plate configured to: receive the magnetic field from the inductive power generator; and in response to receiving the magnetic field, generate an eddy current and heat a portion of the roller to thermally expand a diameter of the roller. 2 . The roller system of claim 1 , wherein the heater plate comprises: a first ring to generate the eddy current and heat; and a second ring, thermally coupled to the first ring, and to transfer the heat from the first ring to the portion of the roller. 3 . The roller system of claim 2 , wherein the first ring comprises a ferromagnetic material configured to generate the eddy current in response to receiving the magnetic field. 4 . The roller system of claim 2 , wherein the second ring comprises a thermally conductive material configured to transfer heat generated by the eddy current to the roller. 5 . The roller system of claim 1 , wherein the heater plate is configured to be secured to an end portion of the roller. 6 . The roller system of claim 5 , wherein the inductive power generator comprises one or more induction heating coils disposed adjacent to an end of the roller. 7 . The roller system of claim 6 , wherein the one or more induction heating coils are fixed while the roller rotates. 8 . The roller system of claim 1 , further comprising a control unit coupled to the inductive power generator and to operationally control the heating of the portion of the roller. 9 . The roller system of claim 8 , wherein the control unit is to utilize input from at least one temperature sensor that measures temperature along the roller to dynamically adjust the heating of the portion of the roller. 10 . The roller system of claim 8 , wherein the control unit is to control the inductive power generator using a closed-loop Proportional-Integral-Derivative (PID) control system based on at least one of thickness or loading density of the material layer as measured by in-line metrology equipment. 11 . A kit for retrofitting a roller system to reduce thermal crowning, comprising: an induction heating system to generate a magnetic field; and a heater assembly configured to be thermally coupled to a roller, the heater assembly to: receive the magnetic field from the induction heating system; and in response to receiving the magnetic field, generate heat to thermally expand at least a portion of the roller when thermally coupled to the roller. 12 . The kit of claim 11 , wherein the heater assembly comprises: a first component made of a ferromagnetic material to generate eddy currents in response to receiving the magnetic field; and a second component made of a thermally conductive material to transfer heat generated by the eddy currents to the roller. 13 . The kit of claim 11 , wherein the induction heating system comprises one or more induction heating coils configured to be disposed adjacent to one or both ends of the roller. 14 . The kit of claim 13 , wherein the one or more induction heating coils are configured to be fixed to bearing blocks supporting the roller while the roller rotates. 15 . The kit of claim 13 , wherein the one or more induction heating coils are split into two parts to accommodate a journal of the roller. 16 . The kit of claim 11 , further comprising: one or more temperature sensors to monitor a temperature of the roller; and a control unit configured to control the induction heating system based on feedback from the one or more temperature sensors. 17 . The kit of claim 16 , wherein the control unit to control the induction heating system based on at least one of thickness or loading density of a material layer. 18 . The kit of claim 11 , wherein the heater assembly comprises: a first ring having a first inner diameter and a first outer diameter; and a second ring having a second inner diameter less than the first inner diameter and a second outer diameter substantially the same as the first outer diameter, the first ring and the second ring coupled to each other such that the first and second outer diameters are substantially aligned. 19 . The kit of claim 18 , wherein the first ring and the second ring each comprise a first half and a second half, wherein the first half of the first ring is coupled to the first half of the second ring, and wherein the second half of the first ring is coupled to the second half of the second ring. 20 . A method of manufacturing an electrode for an energy storage device using a roller system comprising an induction heating system and a heater assembly coupled to a roller, the method comprising: generating a magnetic field using the induction heating system; receiving the magnetic field at the heater assembly coupled to the roller; generating heat in the heater assembly in response to receiving the magnetic field; thermally expanding at least a portion of the roller using the generated heat; determining that the roller is sufficiently heated; and in response to determining that the roller is sufficiently heated, performing a roller operation to form the electrode.