Boyle's Law: Formulation

Below is a table of data presented by Robert Boyle in 1662. Boyle and an assistant carried out an experiment involving a large U-shaped tube closed at the top of one side. Enough mercury was poured into the open end to trap some gas in the closed end. Additional mercury was poured into the open end, which had the effect of compressing the air in the closed end. Column A is the height of the column of air in the closed end, in arbitrary units; one can also think of it as a measure of the volume of the air. Column B is the excess height of the mercury column, the difference in height of the mercury in the open and closed tubes; it represents the pressure beyond atmospheric pressure that is applied to the gas. Column C, a constant, is the height of a column of mercury (in the same apparatus) that would balance atmospheric pressure; thus it represents atmospheric pressure. Column D is the sum of columns B and C; thus it represents the total pressure on the gas.

A B C D E
height of air excess height of mercury height of mercury balancing atmosphere total height of mercury
(volume) ("excess" pressure) (atmospheric pressure) (total pressure)
48 0 29.125 29.125
46 1.4375 29.125 30.5625
44 2.8125 29.125 31.9375
42 4.375 29.125 33.5
40 6.1875 29.125 35.3125
38 7.875 29.125 37
36 10.125 29.125 39.3125
34 12.5 29.125 41.625
32 15.0625 29.125 44.1875
30 17.9375 29.125 47.0625
28 21.1875 29.125 50.3125
26 25.1875 29.125 54.3125
24 29.6875 29.125 58.8125
23 32.1875 29.125 61.3125
22 34.9375 29.125 64.0625
21 37.9375 29.125 67.0625
20 41.5625 29.125 70.6875
19 45 29.125 74.125
18 48.75 29.125 77.875
17 53.6875 29.125 82.75
16 58.125 29.125 87.875
15 63.9375 29.125 93.0625
14 71.3125 29.125 100.4375
13 78.6875 29.125 107.8125
12 88.4375 29.125 117.5625
(Download a copy of the Boyle data in a spreadsheet file by clicking here.)

A	B	C	D	E
height of air	excess height of mercury	height of mercury balancing atmosphere	total height of mercury
(volume)	("excess" pressure)	(atmospheric pressure)	(total pressure)
48	0	29.125	29.125
46	1.4375	29.125	30.5625
44	2.8125	29.125	31.9375
42	4.375	29.125	33.5
40	6.1875	29.125	35.3125
38	7.875	29.125	37
36	10.125	29.125	39.3125
34	12.5	29.125	41.625
32	15.0625	29.125	44.1875
30	17.9375	29.125	47.0625
28	21.1875	29.125	50.3125
26	25.1875	29.125	54.3125
24	29.6875	29.125	58.8125
23	32.1875	29.125	61.3125
22	34.9375	29.125	64.0625
21	37.9375	29.125	67.0625
20	41.5625	29.125	70.6875
19	45	29.125	74.125
18	48.75	29.125	77.875
17	53.6875	29.125	82.75
16	58.125	29.125	87.875
15	63.9375	29.125	93.0625
14	71.3125	29.125	100.4375
13	78.6875	29.125	107.8125
12	88.4375	29.125	117.5625

Pretend you do not know Boyle's Law, and that you are looking for a relationship between the pressure and the volume (either the excess pressure or the total pressure).
a) Plot the pressure and the excess pressure vs. the volume (on the same plot, preferably). Does there appear to be a smooth relationship or a random one? If there is a smooth relationship, is it positive or negative or neither?
b) Take the natural logs of the volume and the pressure (total and excess). Plot the logs of the pressures vs. the log of the volume. Is the result of either plot a straight line? If so, note the slope m and y-intercept b, and write the resulting equation y = mx + b in terms of the pressure p and the volume V.
c) Boyle's table contained a fifth column, E, a calculation of the total pressure based on the law he hypothesized from the data. Make a fifth column and calculate the pressure based on the pressure-volume relationship you derive in part b.

Reference

Robert Boyle, A Defence of the Doctrine Touching the Spring And Weight of the Air (1662)

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