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Delicate quantum entanglement might endure the turmoil of chemical reactions

Updated: Jul 4

By: April Carson



In a groundbreaking discovery, researchers have found that the delicate quantum properties of molecules can withstand the seemingly chaotic environment of chemical reactions. This revelation holds potential not only for advancing quantum technologies but also for uncovering hidden quantum phenomena in nature.


Understanding Quantum Chaos in Chemical Reactions


Traditionally, chemical reactions are perceived as highly chaotic events. As Lingbang Zhu from Harvard University describes, "Typically, people describe chemical reactions as a very chaotic thing: you put a whole bunch of atoms in there, they do a little ‘dance’ and then when products are formed, they just fly out." Zhu and his team embarked on a study to explore how these turbulent reactions impact the quantum characteristics of molecules.


Quantum objects, such as molecules, exhibit dual characteristics, acting as both particles and waves. This duality is encapsulated in a property known as coherence, which highlights the wave-like behavior of molecules. Closely linked to coherence is quantum entanglement, a phenomenon where particles become interconnected in such a way that the state of one instantly influences the state of the other, regardless of the distance separating them. By examining coherence, the researchers aimed to gain insights into the resilience of quantum entanglement during chemical reactions.


The Experimental Setup: Cooling Atoms to Near Absolute Zero


To investigate these quantum properties, the researchers focused on potassium and rubidium atoms. Quantum properties are most pronounced at extremely low temperatures, so the team cooled the atoms to just billionths of a degree above absolute zero. This remarkable feat was achieved by placing the atoms in a vacuum chamber and subjecting them to a meticulously controlled combination of laser beams, magnetic fields, and microwave pulses.


Implications for Quantum Technologies and Natural Phenomena


The results of this study could have far-reaching implications. If quantum entanglement and coherence can survive the chaos of chemical reactions, this resilience might be harnessed in the development of quantum technologies. These technologies, which leverage the unique properties of quantum mechanics, promise revolutionary advancements in computing, communication, and sensing.


Moreover, this research might unveil previously unknown quantum phenomena in natural processes. Understanding how quantum characteristics endure in complex environments could provide deeper insights into the fundamental workings of nature.


The discovery that fragile quantum entanglement can persist through the turmoil of chemical reactions marks a significant step forward in quantum science. As researchers continue to explore these strange and fascinating quantum properties, we can anticipate exciting developments in both technology and our understanding of the natural world. The dance of atoms, it seems, is not just a chaotic frenzy but a performance rich with quantum intrigue.








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About the Blogger:


April Carson is a remarkable individual whose life has been shaped by her determination, dedication, and unwavering passion for both education and sports. Born as the daughter of Billy Carson, she embarked on a journey that would lead her to outstanding achievements and a profound impact on her community.


April's academic journey commenced at Jacksonville University, where she pursued her love for the Social Sciences. She quickly distinguished herself as a diligent student, displaying an insatiable curiosity for understanding the world around her. Her commitment to her studies was matched only by her desire to make a difference in her chosen field.


While her academic pursuits were certainly impressive, it was April's involvement in sports that truly set her apart. She was not just a student at Jacksonville University; she was also a vital member of the Women's Basketball team. On the court, April's dedication and talent were evident for all to see. She exhibited leadership, teamwork, and a relentless drive to excel, qualities that would become hallmarks of her personality both on and off the court.





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