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World's most expensive powder which can be sold for a staggering $140,000,000 per gram

News - Mar 27, 2024
World's most expensive powder which can be sold for a staggering $140,000,000 per gram

Scientists have recently made an astonishing revelation about a material that is considered the most expensive substance in the world.

Known as Nitrogen Atom-Based Endohedral Fullerenes, this powder commands an astounding price of $140,000,000 per gram for its unique properties and transformative potential.

Nitrogen Atom-Based Endohedral Fullerenes is the world's priciest substance. Image Credit: Getty
Nitrogen Atom-Based Endohedral Fullerenes is the world's priciest substance. Image Credit: Getty

While substances like cocaine, heroin, and LSD are really costly, they still do not surpass the most expensive materials in the world.

Industrial elements like platinum and tritium, utilized in the production of luminous signs, rank higher on the price scale. 

Additionally, illicit drugs with high market values per gram, such as cocaine, heroin, and LSD, fall short when compared to a material that can fetch an astonishing $140 million per gram.

Industrial elements like platinum and tritium surpass illicit drugs in price, but a $140 million per gram material tops them all. Image Credit: Getty
Industrial elements like platinum and tritium surpass illicit drugs in price, but a $140 million per gram material tops them all. Image Credit: Getty

Why does this substance have a sky-high cost?

The reason why Nitrogen Atom-Based Endohedral Fullerenes is so expensive is because of its unique uses and the potential advancements it can bring to technology.

One of the most promising applications is its potential to revolutionize atomic clocks. 

Atomic clocks are essential components of GPS systems, playing a crucial role in navigation. However, current atomic clocks are bulky, occupying the size of an entire room. 

Nitrogen Atom-Based Endohedral Fullerenes hold promise in revolutionizing bulky atomic clocks used in GPS navigation. Image Credit: getty
Nitrogen Atom-Based Endohedral Fullerenes hold promise in revolutionizing bulky atomic clocks used in GPS navigation. Image Credit: getty

The advent of Nitrogen Atom-Based Endohedral Fullerenes could change this landscape entirely. 

By utilizing the characteristics of this material, scientists have the potential to create smaller yet highly precise atomic clocks. 

Just imagine the stark contrast of replacing bulky IBM computers with compact smartphones. Making atomic clocks smaller has the potential to completely transform how they are used. 

It could revolutionize their applications in different areas and allow for incredibly precise measurements in a wide range of settings. 

This material allows for smaller, more accurate atomic clocks, benefiting scientific advancements. Image Credit: Getty
This material allows for smaller, more accurate atomic clocks, benefiting scientific advancements. Image Credit: Getty

Making atomic clocks smaller doesn't just reduce their size, it has even greater consequences. 

It opens up the possibility of integrating atomic clocks into devices like smartphones. 

This advancement would have widespread effects, improving the accuracy of location tracking and eliminating areas where GPS signals are weak. 

By having an atomic clock built into the device, precise timing becomes readily available. 

The impact of this technology could revolutionize industries that rely on accurate timing, such as telecommunications, transportation, and scientific research. 

Integrating atomic clocks into smartphones improves location accuracy and eliminates weak GPS signals. Image Credit: Getty
Integrating atomic clocks into smartphones improves location accuracy and eliminates weak GPS signals. Image Credit: Getty

It would enhance the efficiency and reliability of various systems and open the way for new advancements and applications that require accurate timekeeping.

Oxford scientists developed "fullerenes," named after architect Richard Buckminster Fuller.

Oxford scientists at Designer Carbon Materials have made significant breakthroughs in developing Nitrogen Atom-Based Endohedral Fullerenes.

This amazing material gets its name, "fullerenes," due to its special structure with a cage made of carbon atoms with a nitrogen atom inside. 

The material,
The material, "fullerenes," is named after Richard Buckminster Fuller, an architect and philosopher. Image Credit: Getty

The name is a tribute to Richard Buckminster Fuller, an architect and philosopher, renowned for his innovative designs that featured interconnected triangles in geodesic domes. 

This achievement showcases the power of scientific exploration and the potential for developing new materials that can shape the future of technology and scientific advancements.