In Table 1 and Figure 1, the energy required in joules per mL is shown. For Trial 1 of distillation, 16137.93 joules were required per mL of deuterium depleted water, the second largest number of joules. In the second trial, the highest number by 662.07 joules, 16800 joules were required per mL of deuterium depleted water. For electrolysis, only 19.94 joules per mL of deuterium depleted water was required, requiring least energy with 16117.99 joules less than the first trial of distillation, and 16780.06 joules less than the second trial. To calculate the number of joules per mL, the water output in Table 1 and Figure 2 is recorded, as well as the time, volts, current, total KWH, and total watts for each method in Table 1. In the water output, a general downward curve in output was detected, with 58mL being produced the first trial of distillation, 30 the second trial of distillation, and 4.4mL in electrolysis. As in Table 1 again and Figures 3-5, 0.16% of deuterium was detected in both trials of distillation, while for electrolysis 0.15% of deuterium was detected, and in the control 5.22% of deuterium. In Figure 5, the graph was nearly flat until an abrupt change fot the control sample. Therefore, the electrolysis had 0.01% less deuterium than distillation, and 4.07% less deuterium than the control, while the distillation had 4.06% less deuterium than the control. It was observed that electrolysis was better in both ways, requiring approximately 0.12% of the energy required in both distillation trials, so much that it is barely visible on the graph.