The science they discussed to support this conclusion would be from a series of studies they researched. The science behind lead shielding is that lead is typically really dense so it can block radiation more effectively. Because the element is dense, radiation particles have a higher chance of hitting the lead atoms and deflecting when traveling through it. The science behind the lead batteries involves the breaking and making of bonds; these bond formations are typically made with lead sulfate and water. There are several chemical processes, that involve lead, inside of the battery that give off energy. These reactions are also reversible which makes these batteries rechargeable. Finally, the last advantage point the group specifically discussed is the fact that lead is also very malleable. It can be used to create many metal alloys, sheets, cables, and
The science they discussed to support this conclusion would be from a series of studies they researched. The science behind lead shielding is that lead is typically really dense so it can block radiation more effectively. Because the element is dense, radiation particles have a higher chance of hitting the lead atoms and deflecting when traveling through it. The science behind the lead batteries involves the breaking and making of bonds; these bond formations are typically made with lead sulfate and water. There are several chemical processes, that involve lead, inside of the battery that give off energy. These reactions are also reversible which makes these batteries rechargeable. Finally, the last advantage point the group specifically discussed is the fact that lead is also very malleable. It can be used to create many metal alloys, sheets, cables, and