Acanthochronology
Acanthochronology is the study of cactus spines or Euphorbia thorns grown in time ordered sequence (i.e. in series). Physical, morphological or chemical characteristics and information about the relative order or absolute age of the spines or thorns is used to study past climate or plant physiology.
For example, columnar cactus spines grow from the apex of the plant. After several weeks the spines stop growing and have been moved to the side of the stem. The old spines remain in place for decades as new spines are created at the continually growing apex.[1] The result is that along each external "rib" of the cactus is a series of spines arranged in the order they grew in – the oldest spines are at the bottom and the youngest spines are at the top. These spines can be dated using bomb-spike[2] Carbon-14 and isotopes of carbon (Carbon-13) and oxygen (Oxygen-18) may be used to infer past climate[3] (e.g. precipitation or temperature), plant stem growth[4] or plant physiology (e.g. photosynthetic processes)[5]. Alternatively, the width of small transverse bands[6] in the spine may be used to infer daily information about cloud cover or plant productivity, although this remains to be tested. It has also been shown that regular waxy banding on the sides of a Costa Rican cactus (Lemaireocereus aragonii) indicate annual growth and can be used as temporal chronometers.[7]
This sub-discipline of paleoclimatology and ecophysiology is relatively new. Acanthochronology is closely related to dendrochronology, dendroclimatology and isotope geochemistry and borrows many of the methods and techniques from these sub-disciplines of the Earth Sciences. It also draws heavily from the field of ecophysiology, a branch of Biology, to ascribe spine or thorn characteristics to particular environmental or physiological variables.
The first peer-reviewed article[3] to present and explain an isotope spine series was from a saguaro cactus in Tucson, Arizona. This and other work[6][4] shows that radiocarbon and isotope time-series derived from spines can be used for demographic or palaeoclimate studies.
References
- Mauseth, J. D (2006). "Structure-Function Relationships in Highly Modified Shoots of Cactaceae". Annals of Botany. 98 (5): 901–926. doi:10.1093/aob/mcl133. PMC 2803597. PMID 16820405.
- Hua, Quan; Barbetti, Mike (2004). "Review of Tropospheric Bomb 14C Data for Carbon Cycle Modeling and Age Calibration Purposes". Radiocarbon. 46 (3): 1273–1298. doi:10.1017/s0033822200033142.
- English, Nathan B; Dettman, David L; Sandquist, Darren R; Williams, David G (2007). "Past climate changes and ecophysiological responses recorded in the isotope ratios of saguaro cactus spines". Oecologia. 154 (2): 247–258. doi:10.1007/s00442-007-0832-x.
- Delgado-Fernández, Mariana; Garcillán, Pedro P; Ezcurra, Exequiel (2016). "On the Age and Growth Rate of Giant Cacti: Radiocarbon Dating of the Spines of Cardon (Pachycereus Pringlei)". Radiocarbon. 58 (3): 479–490. doi:10.1017/RDC.2016.25.
- Hultine, Kevin R; Dettman, David L; English, Nathan B; Williams, David G (2019). "Giant cacti: isotopic recorders of climate variation in warm deserts of the Americas". Journal of Experimental Botany. 70 (22): 6509–6519. doi:10.1093/jxb/erz320.
- English, Nathan B; Dettman, David L; Sandquist, Darren R; Williams, David G (2010). "Daily to decadal patterns of precipitation, humidity, and photosynthetic physiology recorded in the spines of the columnar cactus,Carnegiea gigantea". Journal of Geophysical Research: Biogeosciences. 115: n/a. doi:10.1029/2009JG001008. hdl:20.500.11919/768.
- Buskirk, Ruth E; Otis, Gard W (1994). "Annual Waxy Bands on a Costa Rican Cactus". Biotropica. 26 (2): 229. doi:10.2307/2388815. JSTOR 2388815.
Further reading
- Doménech-Carbó, Antonio (2015). "Dating: An analytical task". Chemtexts. 1. doi:10.1007/s40828-014-0005-6.