In antiquity, the composition of the objects in the universe was based upon a set of basic elements proposed by Aristotle as earth, air, fire, water, and aether. The first four were found on Earth while the planets, stars, and other denizens of the Empyrium were fashioned from a pure, luminous substance called aether (αιθερ). Although Aristotle considered five elements, in India’s Vedic philosophy these were supplemented by the elements of time, direction, mind and soul. All objects in the world were fashioned from combinations of these elements. Ancient philosophers who thought about the universe invariably found themselves thinking in terms of the basic ingredients to all things, which came to be called atomos by the 5th century BCE Greeks such as Democritus, or parmanu in the 6th century BCE by the Vedic sage, Kanada.

By as late as the 15th century alchemists had only succeeded in identifying a few dozen additional compounds beyond Aristotle’s canonical five. Today, the search for the fundamental elements of nature has inexorably led to the discovery of more than 94 naturally occurring ones on Earth, and an additional 24 artificially created with advanced technology. Centuries of scientific investigation and technological advance have also led to a deep understanding of the nature of matter formed from a small collection of basic elements assembled into molecules of bewildering complexity. But the reduction of matter toits most elementary constituents did not end here. Starting in the early 20th century, atoms were also found to be composed of electrons, protons, and neutrons. The heaviest known element, called Oganesson, was discovered in 2002 and has 118 protons, 118 electrons, and 176 neutrons. By mid-century, experiments on protons discovered that they, themselves, were composed of still more elementary objects called quarks. Over time, physicists discovered exactly six different kinds of quarks that were given the humorous names: up (U), down (D), strange (S), charm (C), bottom (B), and top (T). The familiar protons and neutrons only required two of these types, the U and D quarks, assembled into groups of three, for example, a proton consists of the three-quark combination UUD and the neutron has the opposite combination DDU. Hundreds of other, more massive, particles required additional combinations of the six types of quarks to account for them.