The lowest natural temperature ever directly recorded at ground level on Earth is NaNC at the then-Soviet Vostok Station in Antarctica on 21 July 1983 by ground measurements.[1]
On 10 August 2010, satellite observations showed a surface temperature of NaNC at, along a ridge between Dome Argus and Dome Fuji, at 3900sigfig=3NaNsigfig=3 elevation.[2] The result was reported at the 46th annual meeting of the American Geophysical Union in San Francisco in December 2013; it is a provisional figure, and may be subject to revision.[3] The value is not listed as the record lowest temperature as it was measured by remote sensing from satellite and not by ground-based thermometers, unlike the 1983 record.[4] The temperature announced reflects that of the ice surface, while the Vostok readings measured the air above the ice, and so the two are not directly comparable. More recent work[5] shows many locations in the high Antarctic where surface temperatures drop to approximately NaNC. Due to the very strong temperature gradient near the surface, these imply near-surface air temperature minima of approximately NaNC.
On 21 January 1838, a Russian merchant named Neverov recorded a temperature of NaNC in Yakutsk.[6] On 15 January 1885, H. Wild reported that a temperature of NaNC was measured in Verkhoyansk.[6] A later measurement at the same place in February 1892 was reported as NaNC. Soviet researchers later announced a recording of NaNC in February 1933 at Oymyakon, about 650km (400miles) to the south-east of Verkhoyansk; this measurement was reported by Soviet texts through the 1940s as a record low, with the previous measurement from Verkhoyansk retroactively adjusted to NaNC.[7]
The next reliable measurement was made during the 1957 season at the Amundsen–Scott South Pole Station in Antarctica, yielding NaNC on 11 May and NaNC on 17 September.[6] The next world record low temperature was a reading of NaNC, measured at the Soviet Vostok Station in 1968, on the Antarctic Plateau. Vostok again broke its own record with a reading of NaNC on 21 July 1983.[8] This remains the record for a directly recorded temperature.
In 1904 Dutch scientist Heike Kamerlingh Onnes created a special lab in Leiden in the Netherlands with the aim of producing liquid helium. In 1908 he managed to lower the temperature to less than −269 °C (−452.2 F, 4 K), which is four degrees above absolute zero. Only in this exceptionally cold state will helium liquefy, the boiling point of helium being at −268.94 °C (−452.092 F). Kamerlingh Onnes received a Nobel Prize for his achievement.[9]
Onnes' method relied upon depressurising the subject gases, causing them to cool by adiabatic cooling. This follows from the first law of thermodynamics;
\DeltaU=\DeltaQ-\DeltaW
where U = internal energy, Q = heat added to the system, W = work done by the system.
Consider a gas in a box of set volume. If the pressure in the box is higher than atmospheric pressure, then upon opening the gas will do work on the surrounding atmosphere to expand. As this expansion is adiabatic and the gas has done work
\DeltaQ=0
\DeltaW>0
⇒ \DeltaU<0
Now as the internal energy has decreased, so has the temperature.
As of November 2000, nuclear spin temperatures below 100 pK were reported for an experiment at the Helsinki University of Technology Low Temperature Lab. However, this was the temperature of one particular type of motion—a quantum property called nuclear spin—not the overall average thermodynamic temperature for all possible degrees of freedom.[10] At such low temperatures, the concept of "temperature" becomes multifaceted since molecular motion cannot be assumed to average out across degrees of freedom. The corresponding peak emission will be in radio waves, rather than in the familiar infrared, so it is very inefficiently absorbed by neighboring atoms, making it difficult to reach thermal equilibrium.
The Low Temperature Laboratory recorded a record low temperature of 100 pK, or 1.0 × 10−10 K in 1999.[11]
The current apparatus for achieving low temperatures has two stages. The first utilizes a helium dilution refrigerator to get to temperatures of millikelvins, then the next stage uses adiabatic nuclear demagnetisation to reach picokelvins.[11]
Extremely low temperatures are useful for observation of quantum mechanical phases of matter such as superfluids and Bose–Einstein condensates, which would be disrupted by thermal motion.