Rømer scale

Not to be confused with Réaumur scale.
Rømer temperature conversion formulae
from Rømer to Rømer
Celsius [°C] = ([°Rø]  7.5) × 4021 [°Rø] = [°C] × 2140 + 7.5
Fahrenheit [°F] = ([°Rø]  7.5) × 247 + 32 [°Rø] = ([°F]  32) × 724 + 7.5
Kelvin [K] = ([°Rø]  7.5) × 4021 + 273.15 [°Rø] = ([K]  273.15) × 2140 + 7.5
Rankine [°R] = ([°Rø]  7.5) × 247 + 491.67 [°Rø] = ([°R]  491.67) × 724 + 7.5
For temperature intervals rather than specific temperatures,
1 °Rø = 4021 °C = 247 °F
Comparisons among various temperature scales

Rømer (Danish pronunciation: [ ˈʁœːˀmɐ] (also Roemer) is a temperature scale named after the Danish astronomer Ole Christensen Rømer, who proposed it in 1701. It is based on the freezing point of pure water being 7.5 degrees and the boiling point of water as 60 degrees.

Degree measurements

In this scale, the zero was initially set using freezing brine. The boiling point of water was defined as 60 degrees. Rømer then saw that the freezing point of pure water was roughly one eighth of the way (about 7.5 degrees) between these two points, so he redefined the lower fixed point to be the freezing point of water at precisely 7.5 degrees. This did not greatly change the scale but made it easier to calibrate by defining it by reference to pure water. Thus the unit of this scale, a Rømer degree, is 100/52.5 = 40/21 of a kelvin (or of a Celsius degree). The symbol is sometimes given as °R, but since that is also sometimes used for the Rankine scale, the other symbol °Rø is to be preferred. The name should not be confused with Réaumur.

Importance

The Rømer scale is no longer in use but is of some historical importance. Alongside the Newton scale, it was the first calibrated scale. Previous thermometers gave only an indication of whether the temperature was rising or falling, or else were highly inaccurate. For instance the top and bottom marks of thermometers were typically set to the hottest and coldest days respectively of the current year which clearly would vary from year to year.[1] The idea of using two fiduciary points with equally spaced calibration marks between them was completely new.

Rømer was familiar with Galileo's thermoscope and understood that its large inaccuracies were due to it being affected by air pressure as well as temperature. He followed the idea of Ferdinand II of Tuscany of enclosing a liquid in a sealed glass tube which made it immune to pressure changes. Rømer's thermometer was also an improvement in the fluid that he used. He used a mixture of alcohol and water, conveniently available in the form of wine. This avoided the drawbacks of both the low boiling point of pure alcohol and the extreme non-linearity of pure water near freezing.[2][3]

Connectivity to other scales

The inventor of the Fahrenheit scale Daniel Gabriel Fahrenheit learned of Rømer's work and visited him in 1708; in one of his letters Fahrenheit narrates how he borrowed the idea for the scale from this visit, increasing the number of divisions and eventually establishing what is now known as the Fahrenheit scale, in 1724.[4]

Newton published his scale in the same year as Rømer. Newton's system was calibrated between the freezing point of water (0 degrees) and human body temperature (12 degrees); it was less accurate, but unlike Rømer's it was not intended for everyday use, as Newton's interest was in determining the boiling points of metals, which are not readily accessible with Rømer's system based on liquid thermometers.

See also

Notes and references

  1. Don Rittner, A to Z of Scientists in Weather and Climate, page 53, Infobase Publishing, 2009, ISBN 1438109245.
  2. Jonathan Shectman, Groundbreaking Scientific Experiments, Inventions, and Discoveries of the 18th Century, pp. 248-249, Greenwood Publishing Group, 2003 ISBN 0313320152.
  3. Susan Wills, Steven R. Wills, Meteorology: Predicting the Weather, pp. 19-21, The Oliver Press, Inc., 2003 ISBN 1881508617.
  4. Roger W. Coltey, Survey of medical technology, University of Michigan, 1978, p. 29.
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