Picture the absolute silence of an Ohio summer night in August 1977. Inside a cramped control room, astronomer Jerry Ehman is scanning through continuous line-printer paper from an old IBM 1130 computer connected to the "Big Ear" radio telescope. Looking at a sea of low numbers representing ambient cosmic static, he suddenly spots an impossible sequence of characters: 6EQUJ5. Ehman grabs a red pen, circles the sequence, and writes a single word in the margin: "Wow!" This marked the exact moment humanity intercepted a blindingly loud, narrow-band radio signal pouring in from the constellation Sagittarius. For exactly 72 seconds, it was as if a brilliant cosmic beacon was aimed directly at Earth before vanishing into permanent silence.

The SETI (Search for Extraterrestrial Intelligence) community had aligned its instruments based on a foundational 1959 paper by Philip Morrison and Giuseppe Cocconi, which posited that an advanced civilization trying to make interstellar contact would use a universal mathematical constant frequency: the 21-centimeter line ($1,420\text{ MHz}$), which is the natural emission frequency of neutral hydrogen. This frequency sits in a uniquely quiet window of the electromagnetic spectrum known as the "water hole," sandwiched between galactic background noise and quantum noise. The "Wow!" signal sat perfectly on this universal frequency, possessing a narrow bandwidth of less than $10\text{ kHz}$—a classic hallmark of artificial generation, as natural astrophysical phenomena blast messy radio waves across a wide spectrum.

• The Alphanumeric Intensity Scale: The sequence "6EQUJ5" was not a coded message but the telescope's way of measuring signal-to-noise intensity using a base-36 alphanumeric system; the letter "U" indicated an overwhelming surge peaking at an unprecedented 30 to 31 standard deviations above background noise.
• The Fixed Geometry of the Big Ear: Because the football-field-sized Big Ear telescope was entirely stationary and relied on the Earth's rotation to scan the sky, any true, fixed celestial point in deep space would take exactly 72 seconds to pass through its vertical observation window, perfectly matching the signal's duration.
• The Cosmic Doppler Shift: Factoring out a clerical typewriter typo made by the university's purchasing department on the telescope's local oscillator, the signal's true frequency exhibited a 50-kHz blueshift, mathematically implying that the source was moving toward Earth at roughly $10\text{ km/s}$ due to planetary orbital dynamics.
• The Dick Switching Ambiguity: Due to the telescope's "Dick switching" hardware design—which subtracted ambient noise using two side-by-side feed horns but only recorded the absolute magnitude of the channel—scientists were left with two distinct potential coordinate error boxes in Sagittarius, one near Chi Sagittarii and the other near the globular cluster M55.
• Evolving Astrophysical Theories: While a 2017 theory blaming hydrogen clouds from comets was dismantled due to disproportionate energy outputs and tracking data mismatches, a brand-new 2024 theory from Arecibo suggests a rare hydrogen "maser" pulse (the microwave equivalent of a laser) triggered when a massive cold neutral hydrogen cloud was irradiated by a transient magnetar flare.

Source credit: Research for this episode included transcript materials and supporting historical sources accessed 6/9/2026. Content is summarized and adapted for commentary and educational use.