A New Definition of Exoplanet Habitability: Introducing the Photosynthetic Habitable Zone

Hall, Cassandra; Stancil, P. C.; Terry, Jason; Ellison, Courtney K.

doi:10.3847/2041-8213/acccfb

Cited by 5 publications

(2 citation statements)

References 69 publications

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“…They concluded that pigments would need roughly twice the number of 𝜋-electrons for 𝑇 𝑠 < 3000 K compared to 𝑇 𝑠 ∼ 6000 K, arriving to the same conclusion as Duffy et al. Finally, the feasibility of oxygenic photosynthesis, such as microscopic algae (Hall et al, 2023) and vascular plants (Wolstencroft and Raven, 2002), have been considered within a habitable zone. These predicted oxygenic photosynthesis to perform best around hotter F-type stars (6000 < 𝑇 𝑠 < 7500 K).…”

Section: Introductionmentioning

confidence: 84%

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Optimizing photosynthetic light-harvesting under stars: Generalized thermodynamic models

Chitnavis,

Gray,

Rousouli

et al. 2024

Preprint

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Since the law of physics and chemistry are universal, we must be able to use them to determine the feasibility and potential characteristics of photosynthetic life on exoplanets. Photosynthesis is the cornerstone of Earth’s complex biosphere and creates bio-signatures pivotal in the search for life beyond Earth. However, stars of lower temperature (𝑻𝒔) diminish the intersection between the irradiance at an exoplanet's surface and the wavelengths of light (400 nm ≤ 𝝀 < 700 nm) required for oxygenic photosynthesis, which includes Earth’s plants and cyanobacteria. This does not automatically preclude photosynthesis around such stars, since Earth's photosynthetic organisms have developed highly-specialized light-harvesting structures, known as antennae, to overcome extremely light-limiting conditions. Here, we construct a generalized thermodynamic model of a photosynthetic antenna and evaluate photosynthetic performance across various stellar spectra. We demonstrate that the light-harvesting process, entailing the capture of light across a broad area and channeling it to a small reaction centre, encounters an intrinsic entropic barrier that constrains its efficiency. Through structural and energetic optimizations of our model, we uncover strategies to alleviate the entropic barrier, akin to those seemingly adopted during the evolution of cyanobacteria. We propose that a cyanobacterial-like antenna is thermodynamically optimized even for the coolest M-dwarf stars (𝑻𝒔 ∼ 2300 K) while a plant-like antenna would face severe entropic constraints. By incorporating thermodynamics into biology, our models help linearize the search for photosynthesis based on the stellar spectra an exoplanet receives.

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Section: Introductionmentioning

confidence: 84%

“…It should also be noted that ŕaring may actually support volcanism which can replenish atmospheres (Grayver et al, 2022). Overall, a more intricate habitable zone of photosynthesis should be explored in subsequent work (Hall et al, 2023).…”

Section: Discussionmentioning

confidence: 99%

Optimizing photosynthetic light-harvesting under stars: Generalized thermodynamic models

Chitnavis,

Gray,

Rousouli

et al. 2024

Preprint

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Optimizing photosynthetic light-harvesting under stars: simple and general antenna models

Chitnavis,

Gray,

Rousouli

et al. 2024

Photosynth Res

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In the next 10–20 years, several observatories will aim to detect the signatures of oxygenic photosynthesis on exoplanets, though targets must be carefully selected. Most known potentially habitable exo-planets orbit cool M-dwarf stars, which have limited emission in the photosynthetically active region of the spectrum (PAR, $$400< \lambda < 700$$ 400 < λ < 700 nm) used by Earth’s oxygenic photoautotrophs. Still, recent experiments have shown that model cyanobacteria, algae, and non-vascular plants grow comfortably under simulated M-dwarf light, though vascular plants struggle. Here, we hypothesize that this is partly due to the different ways they harvest light, reflecting some general rule that determines how photosynthetic antenna structures may evolve under different stars. We construct a simple thermodynamic model of an oxygenic antenna-reaction centre supercomplex and determine the optimum structure, size and absorption spectrum under light from several star types. For the hotter G (e.g. the Sun) and K-stars, a small modular antenna is optimal and qualitatively resembles the PSII-LHCII supercomplex of higher plants. For the cooler M-dwarfs, a very large antenna with a steep ’energy funnel’ is required, resembling the cyanobacterial phycobilisome. For the coolest M-dwarfs an upper limit is reached, where increasing antenna size further is subject to steep diminishing returns in photosynthetic output. We conclude that G- and K-stars could support a range of niches for oxygenic photo-autotrophs, including high-light adapted canopy vegetation that may generate detectable bio-signatures. M-dwarfs may only be able to support low light-adapted organisms that have to invest considerable resources in maintaining a large antenna. This may negatively impact global coverage and therefore detectability.

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On the importance and challenges of modelling extraterrestrial photopigments via density-functional theory

Illner,

Lingam,

Peverati

2023

Molecular Physics

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A New Definition of Exoplanet Habitability: Introducing the Photosynthetic Habitable Zone

Cited by 5 publications

References 69 publications

Optimizing photosynthetic light-harvesting under stars: Generalized thermodynamic models

Optimizing photosynthetic light-harvesting under stars: Generalized thermodynamic models

Optimizing photosynthetic light-harvesting under stars: simple and general antenna models

On the importance and challenges of modelling extraterrestrial photopigments via density-functional theory

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