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Assembly theory can change our understanding of the universe.
In Glasgow, Scotland, an international team of scientists presented a new theory that harmoniously combines physics and biology. This theory, dubbed "Assembly Theory," offers a new perspective on understanding the emergence of complexity and evolution in nature.
The concept of "Assembly Theory" builds on the team's previous research, which developed an empirically based method that could potentially detect alien life or help create new life forms in the lab. Scientists have previously introduced the concept of the "molecular assembly index", which estimates the complexity of a molecule based on the steps required to create it.
In their latest study, the team introduces a mathematical dimension to the term "Assembly", which quantifies the level of selection required to create a number of complex entities.
"The assembly theory provides a whole new perspective on physics, chemistry, and biology as different perspectives on the same underlying reality," says the study's lead author, Sarah Walker, a theoretical physicist and origin of life researcher at Arizona State University.
The main advantage of the "Assembly Theory" is its applicability. It has proven effective in quantifying selection and evolution in a variety of systems, ranging from simple molecules to complex cellular structures.
"Assembly theory provides a whole new way of looking at the matter that makes up our world," says study co - author Lee Cronin, a professor and chemist at the University of Glasgow.
One of the key points of the theory is the possibility of its experimental verification. "This opens up an exciting opportunity to use Assembly Theory to develop new experiments that could solve the question of the origin of life by creating living systems from scratch in the lab," adds Cronin.
In the field of scientific research, "Assembly Theory" really raises a lot of interesting questions at the intersection of physical and life sciences. It promises to provide deep insights into the complex physics underlying biological complexity and evolutionary innovation.
In Glasgow, Scotland, an international team of scientists presented a new theory that harmoniously combines physics and biology. This theory, dubbed "Assembly Theory," offers a new perspective on understanding the emergence of complexity and evolution in nature.
The concept of "Assembly Theory" builds on the team's previous research, which developed an empirically based method that could potentially detect alien life or help create new life forms in the lab. Scientists have previously introduced the concept of the "molecular assembly index", which estimates the complexity of a molecule based on the steps required to create it.
In their latest study, the team introduces a mathematical dimension to the term "Assembly", which quantifies the level of selection required to create a number of complex entities.
"The assembly theory provides a whole new perspective on physics, chemistry, and biology as different perspectives on the same underlying reality," says the study's lead author, Sarah Walker, a theoretical physicist and origin of life researcher at Arizona State University.
The main advantage of the "Assembly Theory" is its applicability. It has proven effective in quantifying selection and evolution in a variety of systems, ranging from simple molecules to complex cellular structures.
"Assembly theory provides a whole new way of looking at the matter that makes up our world," says study co - author Lee Cronin, a professor and chemist at the University of Glasgow.
One of the key points of the theory is the possibility of its experimental verification. "This opens up an exciting opportunity to use Assembly Theory to develop new experiments that could solve the question of the origin of life by creating living systems from scratch in the lab," adds Cronin.
In the field of scientific research, "Assembly Theory" really raises a lot of interesting questions at the intersection of physical and life sciences. It promises to provide deep insights into the complex physics underlying biological complexity and evolutionary innovation.
