An undated illustration shows the binary star system CPD-29 2176
An undated illustration shows the binary star system CPD-29 2176, located about 11,000 light years from Earth. NOIRLab/National Science Foundation/AURA/J. da Silva/Spaceengine/Handout via REUTERS Reuters

Supernovas are not always so super. These explosions that mark the death of a star often are spectacularly energetic. But once in a while they are a complete dud.

Scientists on Wednesday detailed one of the duds - a massive star that had so much of its material siphoned off by the gravitational tug of a companion star in a stellar marriage called a binary system that by the time it came to explode at the end of its life cycle it could barely manage a whimper.

Its eventual explosion was so tame, in fact, that the collapsed star - now an incredibly dense object called a neutron star - remains in a docile circular orbit with its companion. A more powerful explosion at the very least would have resulted in a more oval-shaped orbit and even could have sent the star and its companion hurtling in opposite directions.

This binary system, studied using a telescope at the Chile-based Cerro Tololo Inter-American Observatory, is located about 11,000 light years from Earth in our Milky Way galaxy in the direction of the constellation Puppis. A light year is the distance light travels in a year, 5.9 trillion miles (9.5 trillion km).

The neutron star's mass is about 1.4 times that of our sun, having previously been 12 times more massive than the sun. Its companion star boasts a mass 18 to 19 times greater than the sun after cannibalizing its mate. The two stars orbit around each other every 59-1/2 days, separated by about eight-tenths of the distance existing between Earth and the sun.

The anemic stellar explosion that did occur was called an "ultra-stripped" supernova. These happen when a massive star collapses as it runs out of fuel in its core, but cannot manage a strong blast because a companion star has sucked off much of its outer layers and removed material that otherwise would be violently ejected into space.

"Since there is little material in the stellar envelope, there is almost no ejecta from the shock of the collapse," said Arizona-based astronomer Noel Richardson of Embry-Riddle Aeronautical University, lead author of the study published in the journal Nature.

Study co-author Clarissa Pavao, an Embry-Riddle undergraduate student studying physics, described the explosion as: "Faint, subtle and passive."

"If there was more of an explosion, the orbit would not be circular," Richardson said. "A normal supernova wouldn't necessarily destroy the companion, but could disrupt the orbit a lot more. It could, for example, give a kick to the system that either makes the orbit much more elliptical or even sends the surviving star and the neutron star on fast trajectories in opposite directions with speeds that could even send them out of the galaxy."

The type of binary system examined in this study is rare, with roughly 10 estimated to exist in a Milky Way populated by about 100-400 billion stars.

Unlike the lonely sun, perhaps half of our galaxy's stars reside in binary systems. Scientists have pondered whether planets capable of harboring life exist in such systems, as depicted, for example, with "Star Wars" character Luke Skywalker's home planet Tatooine.

"We know of some systems that are binaries with planets, but these are harder to confirm, and all of these are for stars with masses like our sun," Richardson said. "In the case of these massive stars, we have not yet detected planets around them. The stars weigh so much more and are more luminous than sun-like stars, making the planet detection more difficult than around the smaller stars."