Over a hundred years ago, Heber Curtis identified the inaugural black hole jet, a tremendous stream of heated plasma emerging from the supermassive black hole located in the core of the Galaxy M87. The James Webb Space Telescope is currently scrutinizing this jet with remarkable precision.

Since its initial observation in 1918, the M87 jet gained fame for being connected to the first imaged black hole in 2019; however, it has been analyzed by various telescopes and is arguably the most extensively studied black hole jet. Yet, many aspects of its behavior, like some intensely luminous regions and darker spiral-shaped sections, still lack thorough explanation. Astronomers suspect these may be the result of jet beam refocusing or varying chains that form upon interacting with new materials like the dense gaseous regions. Nonetheless, the fundamental mechanisms remain elusive.

Recently, Maciek Wielgus from the Institute of Astrophysics in Andalusia, Spain, along with his colleagues, utilized the James Webb Space Telescope (JWST) to further unveil the famous luminous features of the M87 jets. They also succeeded in capturing a striking and less frequently observed counterjet that shoots out in the opposite direction from the other side of the black hole.

Wielgus and his team analyzed data retrieved from another project examining the M87 star, where JWST’s infrared sensors proved particularly effective. The overwhelming starlight complicated the jet analysis, necessitating the data to be re-evaluated to filter out the extraneous light. “This is a classic example of what astronomers often describe as using another’s discarded data,” notes Wielgus.

The first bright region identified in the jet is termed Hubble Space Telescope 1, in acknowledgment of the discovering telescope, and is believed to result from the jet’s compression entering a higher pressure environment. This phenomenon resembles the bright diamond-shaped patterns seen in rocket engine exhausts.

Researchers can also observe the far end of the jet on the opposite side of M87. As it propels away from us at speeds nearing the speed of light, Einstein’s theory of special relativity renders it much dimmer than it inherently is. However, when this beam encounters another area of gas with varying pressures, it expands and becomes perceptible.

This indicates the end of the material foam surrounding M87, alongside the visible termination of the jet nearest to us. With the imaging of the other end of the jet in such detail in infrared, astronomers can commence modeling the gas structures present within this bubble, states Wielgus.

The Mystery of the Universe: Cheshire, England

Join some of the leading scientific minds for a weekend exploring the enigmas of the universe. Engage in an exciting agenda that includes a visit to the renowned Lovell telescope.