Our historical perspective on photosynthesis has evolved greatly since the 18th century. With the advent of innovative scientific technology, we are capable of perceiving the near-perfect efficiency many photosynthetic life forms possess when converting light to electrical energy (Caffarri, et al., 2014). Researchers posit that by applying our current understanding of quantum mechanics to its role in photosynthesis, it is possible to harvest the Sun’s energy for all of humankind (The Royal Society, 2016).
The overall efficiency of photosynthesis, the process of converting sunlight to biomass energy, is relatively low. At most, photosynthetic organisms are relatively inefficient, as limited energy is absorbed and not all absorbed energy is converted into carbohydrate (Marais, et al., 2018). However, the primary light-harvesting period of photosynthesis proceeds with near-perfect quantum efficiency, illustrating that under ideal conditions, nearly every photon absorbed is transferred to the photosynthetic reaction centres (Marais, et al., 2018).
This level of production is inconceivable in classical mechanics, and instead is indicative of phenomena observed in quantum physics, specifically, quantum superposition. At the core of photosynthetic quantum superposition is the theory that when light hits a molecule that can undergo two distinct hydrogen transfer reactions, both the left and right reaction will occur in a quantum superposition (Scholes, et al., 2017). Classical physics, however, states each reaction will proceed one step at a time (Scholes, et al., 2017), disproving the perceived efficiency of photosynthesis.
By defining a particle only in terms of its likelihood to be found in various positions, researchers have determined that an excited photon may occupy multiple spaces at once (Ball, 2018). This revelation of photon dynamics aptly explains the efficiency of photosynthesis; instead of an incoherent “hopping” progression towards the reaction centres, electrons inspect different routes and almost instantaneously identify the most efficient path to Photosystem I or II (Ball, 2018), a process illustrated in Figure 1.
In coordination with superposition, quantum coherence also acts to aid these excited photons—also known as excitons—to instantly determine the most efficient pathway to the reaction centre (Hildner, et al., 2013). Quantum coherence, the existence of excitons at various energy levels, explains how electrons contact the reaction centre so efficiently (Hildner, et al., 2013). Physicists at the University of Glasgow extracted molecules of the light-harvesting system within plants to examine the photons’ response in hopes of understanding the mechanisms of electron travel within energy pathways. They discovered that when directed onto the complex, a fluorescence was emitted, as the excitons within the system moved from high-energy levels to lower energy levels (Hildner, et al., 2013). Remarkably, the fluorescence oscillated between high and low states, demonstrating that despite the system’s variability, the excitons were still able to instantly discover the most efficient route to the reaction centre (Hildner, et al., 2013).
These results are corroborated by O’Reilly and Olaya-Castro (2014) who identified a combination of coherent motions and noisy vibrations within chlorophyll. By integrating these two motions, the chlorophylls become synchronized and an efficient energy transfer is detected, as energy is equally distributed around the antenna (The Royal Society, 2016).
Using modern biomolecular techniques and the information gathered from these experiments, we can advance our understanding of the quantum mechanisms on Earth. Our knowledge surrounding the confirmation of light-harvesting complexes allows us to analyze how quantum effects influence the efficiency of light-harvesting in the natural world and can potentially strengthen artificial light-harvesting machinery. By synthesizing these understandings, we can create more effective solar cells and inspire the advancement of sustainable solar power for people around the world.
Works Cited:
Ball, P., 2018. Is Photosynthesis Quantum-ish? Physics World, 31(4), pp.44–48.
Caffarri, S., Tibiletti, T., Jennings, R.C. and Santabarbara, S., 2014. A Comparison Between Plant Photosystem I and Photosystem II Architecture and Functioning. Current Protein & Peptide Science, 15(4), pp.296–331.
Hildner, R., Brinks, D., Nieder, J.B., Cogdell, R.J. and van Hulst, N.F., 2013. Quantum Coherent Energy Transfer over Varying Pathways in Single Light-Harvesting Complexes. Science AAAS, 340(6139), pp.1448–51.
Marais, A., Adams, B., Ringsmuth, A.K., Ferretti, M., J. Michael, G., Hendrikx, R., Schuld, M., Smith, S.L., Sinayskiy, I., Kruger, T.P.J., Petruccoine, F. and van Grondelle, R., 2018. The Future of Quantum Biology. Journal of the Royal Society Interface, 15, pp.1-14.
O’Reilly, E.J. and Olaya-Castro, A., 2014. Non-classicality of the molecular vibrations assisting exciton energy transfer at room temperature. Nature Communications, 5(1), pp.1-10.
Rammler, T., Wackenhurt, F., zur Oven-Krockhaus, S., Rapp, J., Forchhammer, K., Harter, K. and Meixner, A.J., 2019. Quantum Coherence in the Photosynthesis Apparatus of Living Cyanobacteria. bioRxiv, pp.1-13.
Scholes, G.D., Fleming, G.R., Chen, L.X., Aspuru-Guzik, A., Buchleitner, A., Coker, D.F., Engel, G.S., van Grondelle, R., Ishizaki, A., Jonas, D.M., Lundeen, J.S., McCusker, J.K., Mukamel, S., Ogilvie, J.P., Olaya-Castro, A., Ratner, M.A., Spano, F.C., Whaley, K.B. and Zhu, X., 2017. Utilizing Coherence to Enhance Function in Chemical and Biophysical Systems. Nature, 543(7647), pp.647–656.
The Royal Society. 2016. Quantum physics of plants. [video online] Available at: <https://www.youtube.com/watch?v=vBpsHAxsxAg&ab_channel=TheRoyalSociety> [Accessed 24 Jan. 2021].
Comments
9 Responses to “The Remarkable Process of Photosynthesis”
Hi iSci!
In Dr. Harvey’s first lecture back from winter holidays, he introduced photosynthesis and how our historical understanding of photosynthesis has evolved to using quantum mechanics to explain some organism’s photosynthetic capabilities. This combination of physics and life sciences really interested me, so I decided to spend some time researching this subject. What I found was very intriguing. I was able to combine my interests in the life sciences and physics disciplines while also gaining appreciation for the intricacies of photosynthesis and quantum physics, and their applicabilities in our search for large-scale power supply. If you guys have any feedback or comments please feel free to list them below. Thank you for reading and have a wonderful day!
Rith
Hi Rith!
Wow! I really enjoyed your post. I loved the connections between biomolecular analysis and its applicability to quantum mechanics. I have a few ideas that may improve it.
The first sentence of your post is quite lengthy and could probably be split into two separate sentences. This may help improve the flow of the first paragraph.
The first sentence of the second paragraph could also be split, but the main concern would be the flow of the sentence. Simply rearranging the first few phrases:
Photosynthesis, the process of converting sunlight to biomass energy, has relatively low efficiency. At most, photosynthetic organisms are a few percent efficient, as they neither absorb all accessible energy nor convert all absorbed energy to carbohydrates(citation).
Let me know what you think!
Good luck with your post!
Halaina
Hi Halaina,
Thank you for the precise feedback. I have edited the first sentences of the first two paragraphs like you mentioned.
Rith
Hey Rith.
Great post! I really enjoyed the content and had a great time reading it. A few things I would change:
-the first sentence could be cut at “century” and then a new sentence could begin from there.
-“mankind” could be changed to “humankind” just because it sounds better and is now considered more inclusive
-if the word count is not maxed, you could add a short sentence explaining quantum coherence would be nice
That’s it! I tried hard to find more to correct but I honestly count find anything. Great job!
Micah Eckert
Hi Micah,
Thank you for your suggestions. I have implemented them into my final draft.
Rith
Hi Rith,
I am so glad you decided to post about this topic! I did some reading on the basics of quantum mechanics over the winter break and I think you did a great job describing the concepts at play at an appropriate level.
-Excellent job using your citation placement to show which material is your original ideas and which is from a source (I have been trying to improve this in my own work lately!) The end of your third paragraph is a great example of this.
-I agree with Halaina’s proposed edit to the beginning of your second paragraph—this will really help with the flow of that section. Also, I agree that breaking up your very first sentence into two sentences will provide a stronger opening to your piece.
-If word count permits, perhaps consider including an example near the end of your post of a research team that is already making use of this idea to build better solar cells (assuming there’s one out there!) This would really give some concrete real-world context to back up your claim at the very end of your conclusion.
Once again, congratulations on a well-written and super enjoyable post!
-Maya
Hi Maya,
Thank you for your comments, they were super helpful. Due to being a little strained on the word count, I am not able to add the name of the research team, but it is the same group working at the University College of London who discovered the coherent and noisy vibration in photosynthetic organisms. Thank you again for your help!
Rith
Hi Rith,
This was a super informative blog post and a great start to the current cutting edge research surrounding photosynthesis. Here are a couple of comments to help you improve your blog post.
1) I would recommend including a figure that describes the concept of photosynthetic quantum superposition in comparison to classical physics. This would help the reader to more intuitively understand what the major differences are.
2) A citation should be included after this sentence: “Researchers posit that by applying our current understanding of quantum mechanics to its role in photosynthesis, it is possible to harvest the Sun’s energy for all of mankind”. Without a citation, this sentence does not seem credible since we do not know who is saying or supporting this statement.
All in all, great work on this blog post!
Jonathan
Hi Jon,
Thank you for your comments, I have implemented both into my final draft. Figure 1 shows the contrast between classical photosynthesis (A) and the quantum mechanical understanding of photosynthesis (B). I have also added the citation.
Rith