Post by account_disabled on Feb 13, 2024 6:20:41 GMT -5
Despite its height, the Eiffel Tower is able to support a large amount of weight due to its geometric arrangement. We tried to recreate this idea at the nanoscale. Generally, when a material's density decreases, its strength also decreases. To solve this problem of direct proportion, MIT scientists developed a structural design based on mathematics that pointed out the best way to distribute weight and direct loads. Therefore, even if the structure becomes lighter, it continues to maintain its strength, which is what happened with the .
Eiffel Tower. Printing The mathematics to design ultra-light and ultra-strong structures has been around for some time, but so far has not been physically realized at the nanostructure level. material Cambodia Telemarketing Data has a similar hardness to rubber, and if it had the density of rubber, it would be three times as strong. This means it can support objects ten thousand times its own weight. The scientists tested the manufacturing process using printing techniques of metals, ceramics and polymers, ultimately obtaining .
Materials with the same properties. These structures can have a variety of uses, from applications in batteries for electronic devices to the construction of parts for the aerospace industry. Not in vain, attempts have been made to use printing to manufacture injectors for its rockets, resulting in significant cost savings. Because these structures are lightweight, launching a spacecraft will not be as expensive because it requires less power. Another potential use for these nanostructures is in controlling sound waves, since they conduct .