BAM, World’s Most Slippery Material Ever
BAM is a material that makes components many times more durable, is the slipperiest material in the world – slipperier than Teflon even! – and is almost like a diamond in hardness.
It is made up of Aluminium, Boron and Magnesium (AlMgB14) along with titanium boride (TiB2) resulting in a substance that is just the third hardest material in the world coming after diamond and cubic boron nitride. This material named BAM (after B, Al and Mg first alphabet) was discovered by the US Department of Energy Ames Laboratory. BAM was formed accidentally in 1999 as experiments were conducted to create a substance that could convert heat energy into electrical energy.
BAM does not have that property but it has other characteristics like super hardness and extremely reduced coefficients of friction (meaning high slipperiness) owing to its unique chemical composition. As it turned out, this material became the world’s best lubricant.
“Its hardness was discovered by accident. We had a terrible time cutting it, grinding it, or polishing it,”
Says a materials scientist Alan Russell, of Iowa State University in Ames.
The accident turned into a benefit as the lab was given $3-million to develop and work on the new material into a substance that could considerably increase the resilience of the material and efficiency of energy. The coefficient of friction for Teflon is 0.05, previously making it the slipperiest material. However, BAM has a coefficient of friction of 0.02 that is even less than half of Teflon’s thus winning the title of the slipperiest material on earth.
Materials engineers would know that usually a substance can exhibit either the property of hardness or of low friction/ slipperiness. Both these characteristics in a single material is an entirely novel phenomenon. Therefore, BAM’s physical properties are being studied thoroughly at present, as it is unclear why the material possesses such capabilities.
Frictional wear is an engineer’s biggest fear as friction causes wear and tear in machines, wastes a lot of energy and adds another layer of complexity to designing machines. Now, BAM has the potential to solve that problem as it has a low coefficient of friction but still maintains its strength. BAM can significantly reduce the tension as it is super slippery and super hard. This will help save useless energy expenditure and increase the longevity of machines beyond imagination.