Provided are a bearing system and a power control method for a bearing device. The bearing system comprises a susceptor; a rotating shaft fixed under the susceptor, where the rotating shaft and the susceptor rotate synchronously; a heating wire located under the susceptor, where the heating wire comprises n heating wire units arranged in a circumferential direction of the susceptor, n2, and temperature of each of the heating wire units is independently controlled; and a power controller configured to: during rotation of the susceptor, control at least one of: a power of a heating wire unit directly under a down end of the susceptor to be less than a power of each of other heating wire units, or a power of a heating wire unit directly under an up end of the susceptor to be greater than a power of each of other heating wire units.

An apparatus and method for initiating thermochemical events in an adiabatic reaction calorimeter are provided. The apparatus and method may be used in safety research of lithium battery and reactive chemical thermal runaways. The apparatus comprises a motor-driven conductive heating element in thermal contact with the outer surface of the reaction in the sample container for heat transfer during heating ramp. The heating element is heated and coupled to the sample container to initiate thermal runaway and transitions to a non-heating configuration once thermal runaway is initiated, which is much faster than many existing slow heating methods used to initiate thermal runaway.

Temperature control systems and methods for a thermal reactor having a process chamber, the control system comprising a first control loop comprising a first Model-Based Predictive Controller (MBPC) and a second control loop comprising a second MBPC, wherein the first and second MBPC are provided with predictive models representing the behavior of the thermal reactor.

Some implementations described herein incorporate a heating system to heat a cover of a bucket. A liquified target material, collected by vanes and/or a transport ring within a vessel of an extreme ultraviolet (EUV) radiation source, flows through a drain port of the transport ring and through a conduit that provides the liquified target material to the bucket through an opening of the cover. By heating the cover, the heating system prevents the liquified target material from solidifying at or near the opening before the liquified target material can flow into the bucket. By preventing the solidifying of the liquid target material, a likelihood of a blockage within the conduit and/or the drain port is reduced.