Origin Page 136
“Simply stated,” England continued, “matter self-organizes in an effort to better disperse energy.” He smiled. “Nature—in an effort to promote disorder—creates little pockets of order. These pockets are structures that escalate the chaos of a system, and they thereby increase entropy.”
Langdon had never thought of it until now, but England was right; the examples were everywhere. Langdon pictured a thundercloud. When the cloud became organized by a static electric charge, the universe created a bolt of lightning. In other words, the laws of physics created mechanisms to disperse energy. The lightning bolt dissipated the cloud’s energy into the earth, spreading it out, thereby increasing the overall entropy of the system.
To efficiently create chaos, Langdon realized, requires some order.
Langdon wondered absently if nuclear bombs might be considered entropic tools—small pockets of carefully organized matter that served to create chaos. He flashed on the mathematical symbol for entropy and realized that it looked like an explosion or the Big Bang—an energetic dispersion in all directions.
“So where does this leave us?” England said. “What does entropy have to do with the origins of life?” He walked over to his chalkboard. “As it turns out, life is an exceptionally effective tool for dissipating energy.”
England drew an image of the sun radiating energy down onto a tree.
“A tree, for example, absorbs the intense energy of the sun, uses it to grow, and then emits infrared light—a much less focused form of energy. Photosynthesis is a very effective entropy machine. The concentrated energy of the sun is dissolved and weakened by the tree, resulting in an overall increase in the entropy of the universe. The same can be said for all living organisms—including humans—which consume organized matter as food, convert it to energy, and then dissipate energy back into the universe as heat. In general terms,” England concluded, “I believe life not only obeys the laws of physics, but that life began because of those laws.”
Langdon felt a thrill as he pondered the logic, which seemed quite straightforward: If blazing sunlight hit a patch of fertile dirt, the physical laws of the earth would create a plant to help dissipate that energy. If deep-ocean sulfur vents created areas of boiling water, life would materialize in those locations and disseminate the energy.
“It is my hope,” England added, “that one day we’ll find a way to prove that life indeed spontaneously emerged from lifeless matter … a result of nothing more than the laws of physics.”
Fascinating, Langdon mused. A clear scientific theory of how life might have self-generated … without the hand of God.
“I am a religious person,” England said, “and yet my faith, like my science, has always been a work in progress. I consider this theory agnostic on questions of spirituality. I am simply trying to describe the way things ‘are’ in the universe; I will leave the spiritual implications to the clerics and philosophers.”
Wise young man, Langdon thought. If ever his theory could be proven, it would have a bombshell effect on the world.
“For the moment,” England said, “everyone can relax. For obvious reasons, this is an extremely difficult theory to prove. My team and I have a few ideas for modeling dissipation-driven systems in the future, but at the moment, we’re still years away.”
England’s image faded, and Edmond reappeared on the screen, standing beside his quantum computer. “I, however, am not years away. This type of modeling is precisely what I’ve been working on.”
He walked toward his workstation. “If Professor England’s theory is correct, then the entire operating system of the cosmos could be summed up by a single overriding command: spread energy!”
Edmond sat down at his desk and began typing furiously on his oversized keyboard. The displays before him filled with alien-looking computer code. “I took several weeks and reprogrammed the entire experiment that had previously failed. I embedded into the system a fundamental goal—a raison d’être; I told the system to dissipate energy at all costs. I urged the computer to be as creative as it could possibly be in its quest to increase entropy in the primordial soup. And I gave it permission to build whatever tools it thought it might need to accomplish that.”
Edmond stopped typing and spun around in his chair, facing his audience. “Then I ran the model, and something incredible happened. It turned out that I had successfully identified the ‘missing ingredient’ in my virtual primordial soup.”
Langdon and Ambra both stared intently at the display wall as the animated graphic of Edmond’s computer model began to play. Again, the visual plunged deep into the churning primordial soup, magnifying down to the subatomic realm, seeing the chemicals bouncing around, binding and rebinding with one another.
“As I fast-forwarded the process and simulated the passage of hundreds of years,” Edmond said, “I saw Miller-Urey’s amino acids taking shape.”
Langdon was not knowledgeable about chemistry, but he certainly recognized the on-screen image as a basic protein chain. As the process continued, he watched as increasingly complex molecules took shape, bonding into a kind of honeycombed chain of hexagons.
“Nucleotides!” Edmond shouted as the hexagons continued to fuse. “We’re watching the passage of thousands of years! And speeding ahead, we see the first faint hints of structure!”
As he spoke, one of the nucleotide chains began wrapping around itself and curling into a spiral. “See that?!” Edmond shouted. “Millions of years have passed, and the system is trying to build a structure! The system is trying to build a structure to dissipate its energy, just like England predicted!”