ONE:"I'll go and look at the gas meter," said Prout.In reasoning up from the world to its first cause, we were given to understand that the two were related to one another as contradictory opposites. The multiple must proceed from the simple, and existence from that which does not exist. But the analogies of material production now suggest a somewhat different view. What every power calls into existence is an image of itself, but the effect is never more than a weakened and imperfect copy of its original. Thus the universe appears as a series of diminishing energies descending in a graduated scale from the highest to the lowest. Here, again, bad science makes bad philosophy. Effects are never inferior to their causes, but always exactly equal, the effect being nothing else than the cause in another place or under another form. This would be obvious enough, did not superficial observation habitually confound the real320 cause with the sum of its concomitants. What we are accustomed to think of as a single cause is, in truth, a whole bundle of causes, which do not always converge to a single point, and each of which, taken singly, is, of course, inferior to the whole sum taken together. Thus when we say that the sun heats the earth, this is only a conventional way of speaking. What really does the work is a relatively infinitesimal part of the solar heat separately transmitted to us through space. Once neglect this truth, and there is no reason why effects should not exceed as well as fall short of their causes in any assignable proportion. Such an illusion is, in fact, produced when different energies converge to a point. Here it is the consequent and not the antecedent which is confounded with the sum of its concomitants, as when an explosion is said to be the effect of a spark.
TWO:Meanwhile a new and powerful agency was about to interpose with decisive effect in the doubtful struggle. This was the study of mathematics. Revived by the Arabians and never wholly neglected during the Middle Ages, it had profited by the general movement of the Renaissance, and was finally applied to the cosmical problem by Galileo. In this connexion, two points of profound philosophical interest must be noted. The first is that, even in its fall, the Aristotelian influence survived, to some extent, both for good and for evil. To Aristotle belongs the merit of having been the first to base astronomy on physics. He maintains the earths immobility on experimental no less than on speculative grounds. A stone thrown straight up in the air returns to its starting-point instead of falling to the west of it; and the absence of stellar385 parallax seems to show that there is no change in our position relatively to the heavenly bodies. After satisfying himself, on empirical considerations, that the popular astronomy is true, he proceeds to show that it must be true, by considerations on the nature of matter and motion, which, although mistaken, are conceived in a genuinely scientific spirit. Now Galileo saw that, to establish the Copernican system, he must first grapple with the Peripatetic physics, and replace it by a new dynamical theory. This, which he could hardly have effected by the ordinary mathematical methods, he did by borrowing the analytical method of Atomism and applying it to the measurement of motion. The law of falling bodies was ascertained by resolving their descent into a series of moments, and determining its rate of velocity at successive intervals; and curvilinear motions were similarly resolved into the combination of an impulsive with an accelerating force, a method diametrically opposed to that of Bacon, who would not even accept the rough analysis of the apparent celestial motions proposed by Greek astronomers.The modern doctrine of evolution, while relying largely on the fertility of multiplied chances, is not obliged to assume such an enormous number of simultaneous coincidences as Epicurus. The ascription of certain definite attractions and repulsions to the ultimate particles of matter would alone restrict their possible modes of aggregation within comparatively narrow limits. Then, again, the world seems to have been built up by successive stages, at each of which some new force or combination of forces came into play, a firm basis having been already secured for whatever variations they were capable of producing. Thus the solar system is a state of equilibrium resulting from the action of two very simple forces, gravitation and heat. On the surface of the earth, cohesion and chemical affinity have been superadded. When a fresh equilibrium had resulted from their joint energy, the more complex conditions of life found free scope for their exercise. The transformations of living species were similarly effected by variation on variation. And, finally, in one species, the satisfaction of its animal wants set free those more refined impulses by which, after many experiments, civilisation has been built up. Obviously the total sum of adaptations necessary to constitute our actual world will have the probabilities of its occurrence enormously increased if we suppose the more general conditions to be established prior to, and in complete independence of, the less general, instead of limiting ourselves, like the ancient atomists, to one vast simultaneous shuffle of all the material and dynamical elements involved.
