\section*{Problem 5} \subsection*{Part A} Xenon-135 is primarily produced in a reactor as a fission product or by the decay of Iodine-135, which is a direct product of uranium fission. Xenon-135 decays naturally over time or can absorb neutrons to become other isotopes with a much smaller neutron cross section. \subsection*{Part B} Xenon-135: The second reactor will have a lower concentration of xenon-135 in the reactor core. Xenon-135 will be generated by the decay of iodine-135, but will also decay naturally to other elements over time as well as being removed through neutron absorption. If the reactors are shut down after a year, the xenon-135 in both will spike with the full power reactor having a larger spike, and it will take longer for the 100\% power reactor to be able to be restarted until the extra xenon-135 has had time to decay away. Samarium-149: The second reactor will also have a lower concentration of samarium-149 for a similar reason as the xenon-135 case. There will be less fissile products to decay into samarium-149 in the low power reactor. If the reactors are powered off, however, both reactors will develop additional samarium-149 concentrations that will not decay away naturally as samarium-149 is stable. It will take more reactivity to restart the full power reactor from shutdown as the samarium-149 concentration will be much higher than the low power reactor. \subsection*{Part C} Xenon is the more challenging poison to deal with. First, xenon has a much larger cross section and has a more significant effect on reactivity than samarium. Second, xenon-135 is not a stable element, and thus has decay effects when the reactor is shut down. As such, the amount of time since shutdown is an important factor to consider when restarting a reactor with consideration to xenon. A miscalculation on xenon concentration can lead to a too-large insertion of reactivity on start-up, which doesn't exist in the same way with samarium as samarium doesn't decay during shutdown. Finally, xenon is a much faster response dynamically compared to samarium. Xenon-135 can quickly change concentrations in hours, while samarium-149 concentrations can take weeks to change significantly. Human operators are much more likely to be able to cope with the longer time constant poison versus misjudging the small time constant effects of xenon.