Proxy (climate)

The ratio between the ¹⁶O and ¹⁸O

In addition to oxygen isotopes, water contains hydrogen isotopes – ¹H and ²H, usually referred to as H and D (for deuterium) – that are also used for temperature proxies. Normally, ice cores from Greenland are analyzed for δ¹⁸O and those from Antarctica for δ-deuterium.^[why?] Those cores that analyze for both show a lack of agreement.^{[citation needed]} (In the figure, δ¹⁸O is for the trapped air, not the ice. δD is for the ice.)

Dendroclimatology is the science of determining past climates from trees, primarily from properties of the annual

Fossil leaves

Paleoclimatologists often use leaf teeth to reconstruct mean annual temperature in past climates, and they use leaf size as a proxy for mean annual precipitation.

Borehole temperatures are used as temperature proxies. Since heat transfer through the ground is slow, temperature measurements at a series of different depths down the borehole, adjusted for the effect of rising heat from inside the Earth, can be "inverted" (a mathematical formula to solve matrix equations) to produce a non-unique series of surface temperature values. The solution is "non-unique" because there are multiple possible surface temperature reconstructions that can produce the same borehole temperature profile. In addition, due to physical limitations, the reconstructions are inevitably "smeared", and become more smeared further back in time. When reconstructing temperatures around 1500 AD, boreholes have a temporal resolution of a few centuries. At the start of the 20th century, their resolution is a few decades; hence they do not provide a useful check on the instrumental temperature record.^[13][14] However, they are broadly comparable.^[3] These confirmations have given paleoclimatologists the confidence that they can measure the temperature of 500 years ago. This is concluded by a depth scale of about 492 feet (150 meters) to measure the temperatures from 100 years ago and 1,640 feet (500 meters) to measure the temperatures from 1,000 years ago.^[15]

Boreholes have a great advantage over many other proxies in that no calibration is required: they are actual temperatures. However, they record surface temperature not the near-surface temperature (1.5 meter) used for most "surface" weather observations. These can differ substantially under extreme conditions or when there is surface snow. In practice the effect on borehole temperature is believed to be generally small. A second source of error is contamination of the well by groundwater may affect the temperatures, since the water "carries" more modern temperatures with it. This effect is believed to be generally small, and more applicable at very humid sites.^[13] It does not apply in ice cores where the site remains frozen all year.

More than 600 boreholes, on all continents, have been used as proxies for reconstructing surface temperatures.^[14] The highest concentration of boreholes exist in North America and Europe. Their depths of drilling typically range from 200 to greater than 1,000 meters into the crust of the Earth or ice sheet.^[15]

A small number of boreholes have been drilled in the ice sheets; the purity of the ice there permits longer reconstructions. Central Greenland borehole temperatures show "a warming over the last 150 years of approximately 1°C ± 0.2°C preceded by a few centuries of cool conditions. Preceding this was a warm period centered around A.D. 1000, which was warmer than the late 20th century by approximately 1°C." A borehole in the Antarctica icecap shows that the "temperature at A.D. 1 [was] approximately 1°C warmer than the late 20th century".^[16]

Borehole temperatures in Greenland were responsible for an important revision to the isotopic temperature reconstruction, revealing that the former assumption that "spatial slope equals temporal slope" was incorrect.

Corals

Pollen can be found in sediments. Plants produce pollen in large quantities and it is extremely resistant to decay. It is possible to identify a plant species from its pollen grain. The identified plant community of the area at the relative time from that sediment layer, will provide information about the climatic condition. The abundance of pollen of a given vegetation period or year depends partly on the weather conditions of the previous months, hence pollen density provides information on short-term climatic conditions.^[18] The study of prehistoric pollen is palynology.

Dinoflagellate cysts

Dinoflagellates occur in most aquatic environments and during their life cycle, some species produce highly resistant organic-walled cysts for a dormancy period when environmental conditions are not appropriate for growth. Their living depth is relatively shallow (dependent upon light penetration), and closely coupled to diatoms on which they feed. Their distribution patterns in surface waters are closely related to physical characteristics of the water bodies, and nearshore assemblages can also be distinguished from oceanic assemblages. The distribution of dinocysts in sediments has been relatively well documented and has contributed to understanding the average sea-surface conditions that determine the distribution pattern and abundances of the taxa (^[19]). Several studies, including ^[20] and ^[21] have compiled box and gravity cores in the North Pacific analyzing them for palynological content to determine the distribution of dinocysts and their relationships with sea surface temperature, salinity, productivity and upwelling. Similarly,^[22] and ^[23] use a box core at 576.5 m of water depth from 1992 in the central Santa Barbara Basin to determine oceanographic and climatic changes during the past 40 kyr in the area.

Lake and ocean sediments

Similar to their study on other proxies, paleoclimatologists examine

• Summer temperature, which shows the energy available to melt seasonal snow and ice
• Winter snowfall, which determines the level of disturbance to sediments when melting occurs
• Rainfall[25]

Diatoms, foraminifera, radiolarians, ostracods, and coccolithophores are examples of biotic proxies for lake and ocean conditions that are commonly used to reconstruct past climates. The distribution of the species of these and other aquatic creatures preserved in the sediments are useful proxies. The optimal conditions for species preserved in the sediment act as clues. Researchers use these clues to reveal what the climate and environment was like when the creatures died.^[26] The oxygen isotope ratios in their shells can also be used as proxies for temperature.^[27]

Water isotopes and temperature reconstruction

Ocean water is mostly H₂¹⁶O, with small amounts of HD¹⁶O and H₂¹⁸O, where D denotes deuterium, i.e. hydrogen with an extra neutron. In Vienna Standard Mean Ocean Water (VSMOW) the ratio of D to H is 155.76x10⁻⁶ and O-18 to O-16 is 2005.2x10⁻⁶. Isotope fractionation occurs during changes between condensed and vapour phases: the vapour pressure of heavier isotopes is lower, so vapour contains relatively more of the lighter isotopes and when the vapour condenses the precipitation preferentially contains heavier isotopes. The difference from VSMOW is expressed as δ¹⁸O = 1000‰ ${\textstyle \times \left({\frac {([{}^{18}O]/[{}^{16}O])}{([{}^{18}O]/[{}^{16}O])_{\mathrm {VSMOW} }}}-1\right)}$; and a similar formula for δD. δ values for precipitation are always negative.^[28] The major influence on δ is the difference between ocean temperatures where the moisture evaporated and the place where the final precipitation occurred; since ocean temperatures are relatively stable the δ value mostly reflects the temperature where precipitation occurs. Taking into account that the precipitation forms above the inversion layer, we are left with a linear relation:

δ ¹⁸O = aT + b

This is empirically calibrated from measurements of temperature and δ as a = 0.67

A study published in 2017 called the previous methodology to reconstruct paleo ocean temperatures 100 million years ago into question, suggesting it has been relatively stable during that time, much colder.[31]

Membrane lipids

A novel climate proxy obtained from

The skill of algorithms used to combine proxy records into an overall hemispheric temperature reconstruction may be tested using a technique known as "pseudoproxies". In this method, output from a climate model is sampled at locations corresponding to the known proxy network, and the temperature record produced is compared to the (known) overall temperature of the model.^[35]

See also

• Carbon dioxide in Earth's atmosphere
• Dendrochronology
• Historical climatology, the study of climate over human history (as opposed to the Earth's)
• Ice core
• Paleotempestology
• Paleothermometer
• Palynology
• Speleothem

References

Further reading

• "Borehole Temperatures Confirm Global Warming Pattern." UniSci. 27 Feb. 2001. 7 Oct. 2009. [1]
• Bruckner, Monica. "Paleoclimatology: How Can We Infer Past Climates?" Microbial Life. 29 Sept. 2008. 23 Nov. 2009. [2]
• "Climate Change 2001: 2.3.2.1 Palaeoclimate proxy indicators." IPCC. 2003. Sept. 23, 2009. [3]
• "Coral Layers Good Proxy for Atlantic Climate Cycles." Earth Observatory. Webmaster: Paul Przyborski. 7 Dec. 2002. 2 Nov. 2009. [4]
• "Core Location Maps." National Ice Core Laboratory. 9 Apr. 2009. 23 Nov. 2009. [5]
• "Dendrochronology." Merriam-Webster Online Dictionary. Merriam-Webster Online. 2009. 2 Oct. 2009. [6]
• Environmental News Network staff. "Borehole temperatures confirm global warming." CNN.com. 17 Feb. 2000. 7 Oct. 2009. [7]
• "The GRIP Coring Effort." NCDC. 26 Sept. 2009. [8]
• "Growth ring." Encyclopædia Britannica. Encyclopædia Britannica Online. 2009. 23 Oct. 2009. [9]
• Huang, Shaopeng, et al. "Temperature trends over the past five centuries reconstructed from borehole temperatures." Nature. 2009. 6 Oct. 2009. [10]
• "Objectives – Kola Superdeep Borehole (KSDB) – IGCP 408: 'Rocks and Minerals at Great Depths and on the Surface.'" International Continental Scientific Drilling Program. 18 July 2006. 6 Oct. 2009. [11]
• "Paleoclimatology: the Oxygen Balance." Earth Observatory. Webmaster: Paul Przyborski. 24 Nov. 2009. 24 Nov. 2009. [12]
• Schweingruber, Fritz Hans. Tree Rings: Basics and Application of Dendrochronology. Dordrecht: 1988. 2, 47–8, 54, 256–7.
• Strom, Robert. Hot House. New York: Praxis, 2007. 255.
• "Varve." Merriam-Webster Online Dictionary. Merriam-Webster Online. 2009. 2 Nov. 2009. [13]
• Wolff, E. W. (2000) History of the atmosphere from ice cores; ERCA vol 4 pp 147–177

External links

Wikimedia Commons has media related to Proxy (climate).

• Chemical climate proxies at Royal Society of Chemistry, January 23, 2013
• Quintana, Favia et al., 2018 ″Multiproxy response to climate- and human-driven changes in a remote lake of southern Patagonia (Laguna Las Vizcachas, Argentina) during the last 1.6 kyr″, Boletín de la Sociedad Geológica Mexicana, Mexico, VOL. 70 NO. 1 P. 173 ‒ 186 [14]