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Scientists at the University of Michigan discover bacteria that transform compounds into PURE 24-karat GOLD

Written by Valdemar Medeiros
Published 08/01/2024 às 23:45
Updated 11/01/2024 às 09:13
Scientists at the University of Michigan discover bacteria that transform compounds into PURE 24-karat GOLD
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Scientists discover bacteria with the unprecedented ability to transform natural compounds into 24-karat gold, a process known as microbial alchemy.

In a surprising breakthrough that combines microbiology and electronic art, two scientists from University of Michigan made an extraordinary discovery. Kazem Kashefi, professor of microbiology, and Adam Brown, associate professor of electronic art, revealed the existence of bacteria capable of transforming natural compounds into 24-karat gold. This remarkable achievement is the result of an interdisciplinary study, which unites science and creativity in a unique way.

Transforming natural compounds into gold is called microbial alchemy

Scientists have unraveled, with their study, the mysteries of unique bacteria capable of converting natural compounds into 24-karat gold. This unusual intersection of disciplines promises to revolutionize human understanding of nature and its surprising capabilities.

Bacteria are called Cupriadivus Metallidurans and has captivated the scientific community for its excellent ability to catalyze the transformation of common natural compounds into pure gold. This process in which matter is converted into 24-karat gold is called microbial alchemy.

The research team, made up of microbiologists and artists, explored the intricacies of this unique phenomenon, which challenges scientific conventions and opens the doors to unexplored applications in the fields of science and art. The two American scientists' study of bacteria details the intriguing process by which Curpiavidus Metallidurans accomplished this astonishing feat.

Bacteria use specialized enzymes to break down surrounding natural compounds, releasing gold particles in a kind of elegant ballet of tiny microbes. This process, in addition to its scientific importance, has inspired researchers to explore new means of artistic expression that capture the beauty of microbiology.

Challenges encountered by scientists duringe study of bacteria

After this discovery by scientists, a multitude of applications open up for modern life. In science, the ability of Cupriavidus metallidurans Synthesizing gold could transform the way the world approaches mining and manufacturing advanced materials.

Furthermore, the fusion of microbiology and electronic art for 24 carat gold generation it can generate new forms of artistic expression that transcend the boundaries between science and creativity. As excitement about this discovery grows, scientists and society at large also face a number of practical and ethical challenges.

Therefore, it is clear that we must ensure adequate management of the application of these bacteria in natural environments and consideration of the environmental implications, which are essential to ensure that this phenomenon does not have harmful effects on the ecosystems that surround the world. A nature, once again, demonstrates his incredible ability to surprise the world and defy expectations.

Other discoveries with bacteria

In addition to this discovery to produce 24-karat gold, scientists from University of Texas, in Austin, report findings that bacteria use iron, a common element yet essential for life on Earth, to store memory across generations.

This iron-mediated memory is linked to the behavior of the bacteria Escherichia coli, namely swarming, the ability to form biofilms and the development of antibiotic resistance.

This and countless other bacteria begin to form biofilms when they find a compatible surface, which may be living or non-living, such as medical tools, industrial machines or fabrics. The formation of biofilms is driven by the availability of nutrients.

In situations where nutrients are abundant, bacteria may choose to develop biofilms to establish a stable environment and maximize efficient use of resources. According to scientists, before there was oxygen in Earth's atmosphere, early cellular life used iron for many cellular processes.

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Valdemar Medeiros

Journalist in training, specialist in creating content with a focus on SEO actions. Writes about the Automotive Industry, Renewable Energy and Science and Technology

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