Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-22T22:06:31.488Z Has data issue: false hasContentIssue false
  • English
  • Français

Planetary mass, vegetation height and climate

Published online by Cambridge University Press:  07 January 2019

David S. Stevenson
David S. Stevenson*
Affiliation:
Carlton le Willows Academy, Wood Lane, Gedling, NG4 4AA, UK
*
Author for correspondence: David S. Stevenson, E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

The maximum height trees can grow on Earth is around 122–130 m. The height is constrained by two factors: the availability of water, and where water is not limiting, the pressure available to drive the column of water along the xylem vessels against the pull of gravity (cohesion tension). In turn the height of trees impacts the biodiversity of the environment in a number of ways. On Earth the largest trees are found in maritime temperate environments along the Pacific Northwest coasts of northern California and southern Oregon. These forests provide a large number of secondary habitats for species and serve as moisture pumps that return significant volumes of water to the lower atmosphere. In this work, we apply simple mathematical rules to illustrate how super-terran planets will have significantly smaller trees, with concomitant effects on the habitability of the planet. We also consider the impact of varying tree height on climate models.

Keywords

Cohesion tensionplanetary masssub-stellar pointsuper-terransynchronous rotationvegetation heightwind velocityxylem
Type
Research Article
Information
International Journal of Astrobiology , Volume 18 , Issue 5 , October 2019 , pp. 477 - 482
Copyright
Copyright © Cambridge University Press 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Alibert, Y (2014) On the radius of habitable planets. Astronomy & Astrophysics 561, A41.Google Scholar
Brienen, RJW, Gloor, E, Clerici, S, Newton, R, Arppe, L, Boom, A, Bottrell, S, Callaghan, M, Heaton, T, Helama, S, Helle, G, Leng, MJ, Mielikäinen, K, Oinonen, M and Timonen, M (2017) Tree height strongly affects estimates of water-use efficiency responses to climate and CO2 using isotopes. Nature Communications 8, 10.Google Scholar
Boutle, IA, Mayne, NJ, Drummond, B, Manners, J, Goyal, J, Lambert, FH, Acreman, DM and Earnshaw, PD (2017) Exploring the climate of Proxima B with the Met Office Unified Model. Available at https://arxiv.org/pdf/1702.08463.pdf.Google Scholar
Cowan, NB and Abbot, DS (2014) Water cycling between ocean and mantle: super-earths need not be waterworlds. The Astrophysical Journal 781, 7.Google Scholar
Dressing, CD and Charbonneau, D (2015) The occurrence of potentially habitable planets orbiting M-dwarfs estimated from the full Kepler dataset and an empirical measurement of the detection sensitivity. The Astrophysical Journal 807, 23.Google Scholar
Frederick, RH (1961) A study of the effect of tree leaves on wind movement. Monthly Weather Review 89, 3944. Available at ftp://ftp.library.noaa.gov/docs.lib/htdocs/rescue/mwr/089/mwr-089-02-0039.pdf.Google Scholar
Friend, AD (1993) The prediction and physiological significance of tree height. In Solomon, AM and Shugart, HH (eds), Vegetation Dynamics and Global Change. New York: Chapman and Hall, pp. 101115.Google Scholar
Haqq-Misra, J, Wolf, ET, Joshi, M, Zhang, X and Kopparapu, RK (2017) Demarcating circulation regimes of synchronously rotating terrestrial planets near the inner edge of the habitable zone. Available at https://arxiv.org/pdf/1710.00435.pdf.Google Scholar
Jacobsen, AL, Pratt, RB, Tobin, MF, Hacke, UG and Ewers, FW (2010) A global analysis of xylem vessel length in woody plants. American Journal of Botany 99, 15831591.Google Scholar
Jasechko, S, Sharp, ZD, Gibson, JJ, Birks, SJ, Yi, Y and Fawcett, PJ (2013) Terrestrial water fluxes dominated by transpiration. Nature 496, 347350.Google Scholar
Jeje, AA and Zimmermann, MH (1979) Resistance to water flow in xylem vessels. Journal of Experimental Botany 30, 817827. Available at https://harvardforest.fas.harvard.edu/sites/harvardforest.fas.harvard.edu/files/publications/pdfs/Jeje_JExptBotany_1979.pdf.Google Scholar
Kim, HK, Park, J and Ildoo Hwang, I (2014) Investigating water transport through the xylem network in vascular plants. Journal of Experimental Botany 65, 18951904.Google Scholar
Kitaya, Y, Tsuruyama, J, Kawai, M, Shibuya, T and Kiyota, M (2000) Effects of air current on transpiration and net photosynthetic rates of plants in a closed plant production system. In Kubota, C and Changhoo, C (eds), Transplant Production in the 21st Century. Dordrecht: Springer, pp. 83–90. ISBN 978-94-015-9371-7.Google Scholar
Kite, ES, Manga, M and Gaidos, E (2009) Geodynamics and rate of volcanism on massive earth-like planets. The Astrophysical Journal 700, 17321749.Google Scholar
Koch, GW and Fredeen, AL (2005) Transport challenges in tall trees. In Holbrook, NM and Zwieniecki, MA (eds), Vascular Transport in Plants. Amsterdam: Elsevier Academic Press, pp. 437456.Google Scholar
Koch, GW, Sillett, SC, Jennings, GM and Davis, SD (2004) The limits to tree height. Nature 428, 851854.Google Scholar
Kopparapu, RK, Wolf, ET, Haqq-Misra, J, Yang, J, Kasting, JF, Meadows, V, Terrien, R and Suvrath Mahadevan, S (2016) The inner edge of the habitable zone for synchronously rotating planets around low-mass stars using general circulation models. The Astrophysical Journal 819, 14. Available at http://iopscience.iop.org/article/10.3847/0004-637X/819/1/84/pdf.Google Scholar
Liu, Y and El-Kassaby, YA (2018) Evapotranspiration and favourable growing degree-days are key to tree height growth and ecosystem functioning: meta-analyses of Pacific Northwest historical data. Scientific Reports 8, 8228.Google Scholar
Maa, W (2017) Study on the water flow in the xylem of plants. AIP Conference Proceedings 1839, 020061–1–4.Google Scholar
Marshall, BJ (1998) Wind Flow Structures and Wind Forces in Forests (Thesis). Available at http://www.eng.ox.ac.uk/civil/publications/theses/marshall_wind.pdf.Google Scholar
Merlis, TM and Tapio Schneider, T (2010) Atmospheric dynamics of earth-like tidally locked aquaplanets. Journal of Advances in Modeling Earth Systems 2, 17.Google Scholar
Mohamed, MA, David, H and Wood, DH (2015) Computational study of the effect of trees on wind flow over a building. Renewables: Wind, Water, and Solar 2, 2.Google Scholar
Niklas, KJ (2007) Maximum plant height and the biophysical factors that limit it. Tree Physiology 27, 433440.Google Scholar
Olson, ME and Rosell, JA (2013) Vessel diameter–stem diameter scaling across woody angiosperms and the ecological causes of xylem vessel diameter variation. New Phytologist 197, 12041213.Google Scholar
Pockman, WT and Sperry, J (2000) Vulnerability to cavitation and the distribution of Sonoran desert vegetation. American Journal of Botany 87, 12871299.Google Scholar
Pockman, WT, Sperry, JS and O'Leary, JW (1995) Sustained and significant negative pressure in xylem. Nature 378, 715716.Google Scholar
Rogers, LA (2015) Most 1.6 Earth-radius planets are not rocky. The Astrophysical Journal 801, 13pp Article ID 41. Available at http://iopscience.iop.org/article/10.1088/0004-637X/801/1/41/pdf.Google Scholar
Rosell, JA, Olson, ME and Anfodillo, T. (2017) Scaling of xylem vessel diameter with plant size: causes, predictions, and outstanding questions. Current Forestry Reports 3, 4659. doi: 10.1007/s40725-017-0049-0. Available at: https://link.springer.com/article/10.1007/s40725-017-0049-0.Google Scholar
Smirnoff, N (1993) Tansley Review No. 52: the role of active oxygen in the response of plants to water deficit and desiccation. New Phytologist 125, 2758.Google Scholar
Stevenson, DS (2018) Evolutionary Exobiology II: investigating biological potential of synchronously-rotating worlds. International Journal of Astrobiology, 115. Available at https://doi.org/10.1017/S1473550418000241.Google Scholar
Stevenson, DS (2019) Red Dwarfs, their Worlds and their Biological Potential. Springer (New York) in press.Google Scholar
Thompson, MV and Holbrook, NM (2003) Application of a single-solute non-steady-state model to the study of long-distance assimilate transport. Journal of Theoretical Biology 220, 419455.Google Scholar
van Ieperen, W, van Meeteren, U and van Gelder, H (2000) Fluid composition influences hydraulic conductance of xylem conduits. Journal of Experimental Botany 51, 769776.Google Scholar
Vautard, R, Cattiaux, J, Yiou, P, Thépaut, JN and Ciais, P (2010) Northern Hemisphere atmospheric stilling partly attributed to an increase in surface roughness. Nature Geoscience 3, 756761. Available at https://www.researchgate.net/publication/51997212.Google Scholar
Virot, E, Ponomarenko, A, Dehandschoewercker, E, Quéré, D and Clanet, C (2016) Critical wind speed at which trees break. Physical Review E 93, 023001-1023001-7.Google Scholar
Vogel, S (1981) Life in Moving Fluids: The Physical Biology of Flow. Boston: Willard Grant Press, pp. 352. Available at https://www.researchgate.net/publication/230891773_Life_in_Moving_Fluids_The_Physical_Biology_of_Flow.Google Scholar
Wheatley, PJ, Louden, T, Bourrier, V, Ehrenreich, D and Gillon, M (2016) Strong XUV irradiation of the Earth-sized exoplanets orbiting the ultracool dwarf TRAPPIST-1. Available at https://arxiv.org/pdf/1605.01564v1.pdf.Google Scholar
Woodruff, DR, Bond, BJ and Meinzer, FC (2004) Does turgor limit growth in tall trees? Plant Cell and Environment 27, 229236.Google Scholar
Xi, W, Peet, RK, Decoster, JK and Urban, DL (2008) Tree damage risk factors associated with large, infrequent wind disturbances of Carolina forests. Forestry 81, 317334.Google Scholar
Zeng, LI, Sasselov, DD and Jacobsen, SB (2016) Mass–radius relation for rocky planets based on PREM. The Astrophysical Journal 819, 5.Google Scholar
Zimmermann, MH (1983) Xylem Structure and the Ascent of Sap. Berlin: Springer-Verlag, pp. 143.Google Scholar
Zwieniecki, MA, Melcher, P and Holbrook, NM (2001 a) Hydraulic properties of individual xylem vessels of Fraxinus americana. Journal of Experimental Botany 52, 257264.Google Scholar
Zwieniecki, MA, Melcher, P and Holbrook, NM (2001 b) Hydrogel control of xylem hydraulic resistance in plants. Science 291, 10591062.Google Scholar