Galileo thermometer
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A Galileo thermometer, Galilean thermometer or thermoscope is a thermometer made of a sealed glass cylinder containing a clear liquid. Suspended in the liquid are a number of weights. Commonly those weights are themselves sealed glass containers with coloured liquid for an attractive effect. As the liquid changes temperature it changes density and the suspended weights rise and fall to stay at the position where their density is equal to that of the surrounding liquid. If the weights differ by a very small amount and are ordered such that the least dense is at the top and most dense at the bottom, they can form a temperature scale.
The temperature is typically read from an engraved metal disc on each weight. The lowest weight of the top set of weights indicates the ambient temperature. To achieve this requires manufacturing the weights to a tolerance of less than 1/1000 of a gram.
[edit] How it works
The Galileo thermometer works due to the principle of buoyancy. Buoyancy determines whether objects float or sink in a liquid, and is responsible for the fact that even boats made of steel can float (of course, a solid bar of steel by itself will sink). The only factor that determines whether a large object will float or sink in a particular liquid relates the object's mass to the mass of the liquid displaced by the object when submerged[1]. If the object's mass is greater than the mass of liquid displaced, the object will sink. If the object's mass is less than the mass of liquid displaced, the object will float.
If there are two objects, each a cube 10 cm by 10 cm by 10 cm. The mass of water displaced by an object of this size is 1 kg. The brown object on the left is floating because the mass of water it is displacing (0.5 kg, half the object is submerged and half is above water) is equal to the mass of the object. The green object on the right has sunk because the mass of water it is displacing (1 kg) is less than the object's mass (2 kg).
Not all objects made of the green material above will sink. In figure 2, the interior of the green object has been hollowed out. The total mass of the object is now 0.5 kg, yet its volume remains the same, so it floats half way out of the water like the brown object in figure 1.
In the examples above, the liquid in which the objects have been floating is assumed to be water. Water has a density of 1 kg/L, which means that the volume of water displaced by any of the above objects is 1 kg.
Galileo discovered that the density of a liquid varies slightly with temperature. As the temperature increases, the density of the liquid decreases. This is the key to how the Galileo thermometer works.
Figure 3 shows a 1 kg hollow object made of the green material. In the left hand container, the density of the liquid is 1.001 kg/L. Since the object weighs less than the mass of water it displaces, it floats. In the right hand container, the density of the liquid is 0.999 kg/L. Since the object weighs more than the mass of water it displaces, it sinks. This shows that very small changes in the density of the liquid can easily cause an almost-floating object to sink.
In the Galileo thermometer, the small glass bulbs are partly filled with a different (coloured) liquid. Each is filled with a slightly different amount, ranging from lightest at the uppermost bulb to heaviest at the lowermost bulb. The clear liquid in which the bulbs are submerged is not water, but some inert hydrocarbon (probably chosen because its density varies with temperature more than water does).
Figure 4 shows a schematic representation of a Galileo thermometer at two different temperatures (the temperature markings on this example are in Fahrenheit).
How to read temperature with a Galilean Thermometer:
If there are some bulbs at the top (Figure 4, left) and some at the bottom, but one floating in the middle, then the one floating in the middle tells the temperature.
If there is not a bulb in the middle (Figure 4, right) then you take the temperature at the bulb at the bottom of the gap, add it to the temperature at the bulb at the top of the gap, and divide the result by two.
[edit] References
- ^ Small objects, such as a pin (device), can float through surface tension.
