The early universe was a place of extremes. It was inconceivably small and scorching, with all the energy and matter there would ever be crammed into a tiny space a billion times hotter than the center of the Sun. In the first moments after the Big Bang, the universe cooled enough to allow fundamental particles — such as quarks and electrons — to spring into being. Quarks combined to form protons and neutrons and, not long after, the nuclei of deuterium, helium, and lithium were formed. Energy zipped around the infant universe in the form of photons, but that early light ricocheted off free electrons, which weren’t yet bound to any atom, at every turn. Fast-forward another 380,000 years, and the universe had cooled enough to allow the early nuclei to pull in electrons and form neutral atoms. (This is called recombination, although it actually marks the first time these particles combined.) This moment ushered in darkness — a period we now call the cosmic dark ages.

Seeing the universe

Looking at an object, either with our eyes or with a telescope, requires photons of light to hit some sort of detector, whether it’s your retina or a camera. But the cosmic dark ages were a time when the universe was enveloped by a fog of neutral hydrogen that trapped the light of the first stars and galaxies.

The fog didn’t lift until 1 billion years after the Big Bang when the neutral hydrogen had been reionized and once again split apart. Because light couldn’t escape its surroundings during the dark ages, it couldn’t journey outward through the universe to hit our detectors here on Earth, nearly 13 billion years later. As a result, trying to peer back at that time is like trying to see a lightbulb through a thick, dark haze. But interesting things were happening, even if we can’t see them. Think of our own Dark Ages here on Earth, between about A.D. 500 and 1000. It may not seem like much happened in terms of scientific or cultural advancement, but stirring beneath the surface were forces that would set in motion the Renaissance. Similarly, the cosmic dark ages were a time of great transformation. “This period is special in the sense that it marks the transition between the universe being very simple and being very complex,” says Avi Loeb, an astronomer at the Harvard-Smithsonian Center for Astrophysics who was among the first to explore this time in the early universe. “Black holes, neutron stars, even life eventually here on Earth ... the roots of it were planted at the dark ages. If we want to understand where we came from, that’s where the story starts.”

The three galaxies (circled in green) that form the EGS77 galaxy group are glowing just 680 million years after the Big Bang. These galaxies have been observed ionizing the atoms around them, generating overlapping bubbles of ionized hydrogen (depicted by an artist in the inset). Astronomers believe that as more galaxies formed over time, such bubbles grew and eventually overlapped throughout the universe, bringing the dark ages to an end. NASA, ESA, AND V. TILVI (ASU)

Astronomers do know what the universe was like just before the dark ages began. That’s because they have an actual image of what conditions were like at that time. When the first neutral atoms formed, the process released photons of light that set off across the universe, creating a cosmic snapshot of the exact conditions at the beginning of their journey. This cosmic microwave background (CMB) radiation, also known as relic radiation, exists all around us today and tells astronomers that the universe was more or less uniform in density at that. time, with only very small ripples in it. But those ripples are important. “If you feed those perturbations into a computer simulation, you get objects like galaxies we see today,” says Loeb. “The dark ages mark the transition that the universe made from these small fluctuations into objects, the first galaxies, the first stars. That’s a major transition.” The precise way in which that transition happened is still poorly understood. What astronomers do know with certainty, however, is why we can’t see any light from objects shining during the dark ages. For starters, there wasn’t much light before the first stars formed. Aside from hydrogen atoms, most of the universe was made up of dark matter, which doesn’t emit light. What’s more, a cosmic fog of neutral hydrogen atoms permeated the universe, scattering or absorbing many of the ultraviolet (UV) photons that the very first stars emitted. “The time it would take for a photon to escape [the hydrogen] was longer than the age of the universe,” explains Bahram Mobasher, a professor of physics and astronomy at the University of California, Riverside. So, the light can’t reach us from that time, however long we wait for it to arrive.

“The first stars and galaxies formed, and their light brought the universe out of the dark ages.”

- Mobastar,

Next Up: The Cosmic Dawn and How new stars are formed.

Stay tuned.

Reference: Article by DANA NAJJAR

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