The difference of velocity in iron and in air may be illustrated by the following instructive experiment: Choose one of the longest horizontal bars employed for fencing in Hyde Park; and let an assistant strike the bar at one end while the ear of the observer is held close to the bar at a considerable distance from the point struck. Two sounds will reach the ear in succession; the first being transmitted through the iron and the second through the air. This effect was obtained by M. Biot, in his experiments on the iron water-pipes of Paris.
The transmission of sound through a solid depends on the manner in which the molecules of the solid are arranged. If the body be homogeneous and without structure, sound is transmitted through it equally well in all directions. But this is not the case when the body, whether inorganic like a crystal or organic like a tree, possesses a definite structure. This is also true of other things than sound. Subjecting, for example, a sphere of wood to the action of a magnet, it is not equally affected in all directions. It is repelled by the pole of the magnet, but it is most strongly repelled when the force acts along the fibre. Heat also is conducted with different facilities in different directions through wood. It is most freely conducted along the fibre, and it passes more freely across the ligneous layers than along them. Wood, therefore, possesses three unequal axes of calorific conduction. These, established by myself, coincide with the axes of elasticity discovered by Savart. MM. Wertheim and Chevandier have determined the velocity of sound along these three axes and obtained the following results:
Velocity of Sound in Wood
| Name of Wood | Along Fibre | Across Rings | Along Rings |
| Acacia | 15,467 | 4,840 | 4,436 |
| Fir | 15,218 | 4,382 | 2,572 |
| Beech | 10,965 | 6,028 | 4,643 |
| Oak | 12,622 | 5,036 | 4,229 |
| Pine | 10,900 | 4,611 | 2,605 |
| Elm | 13,516 | 4,665 | 3,324 |
| Sycamore | 14,639 | 4,916 | 3,728 |
| Ash | 15,314 | 4,567 | 4,142 |
| Alder | 15,306 | 4,491 | 3,423 |
| Aspen | 16,677 | 5,297 | 2,987 |
| Maple | 13,472 | 5,047 | 3,401 |
| Poplar | 14,050 | 4,600 | 3,444 |
Separating a cube from the bark-wood of a good-sized tree, where the rings for a short distance may be regarded as straight: then, if A R, Fig. 14, be the section
Fig. 14. of the tree, the velocity of the sound in the direction m n, through such a cube, is greater than in the direction a b.
The foregoing table strikingly illustrates the influence of molecular structure. The great majority of crystals show differences of the same kind. Such bodies, for the most part, have their molecules arranged in different degrees of proximity in different directions, and where this occurs there are sure to be differences in the transmission and manifestation of heat, light, electricity, magnetism, and sound.