From AAS NOVA: “Holding Together a Speeding Cloud”



20 February 2019
Susanna Kohler

Composite image showing the size and location of the Smith cloud on the sky. The cloud was imaged in radio wavelengths and the sky in optical. Z. Levay—NASA/ESA

Green Bank Radio Telescope, West Virginia, USA, now the center piece of the GBO, Green Bank Observatory, being cut loose by the NSF

High-velocity clouds observed in our galaxy’s halo pose a conundrum: given their tenuous nature and large speeds, why haven’t they been ripped apart? New observations of one such cloud now provide a possible answer.

The Sombrero galaxy, Messier 104, provides an excellent example of a galaxy and its halo — the region that extends above and below the galaxy’s disk. High-velocity clouds have been detected speeding through our own galaxy’s halo. [ESA/C. Carreau]

Plunging Gas

The halo of our galaxy isn’t only host to stars. So-called “high-velocity clouds” — massive collections of gas moving at more than 150,000 mph — zip through the halo, plunging toward and through the galactic disk.

Where does this speedy gas come from? How do the clouds evolve as they pass through the halo? And what protects them from having their gas stripped in the process? There are still many questions about high-velocity clouds that future observations may help us to answer. One cloud in particular makes an ideal target for further exploration: the Smith cloud [above].

A Useful Target

The Smith cloud consists of at least a million solar masses of gas and lies in the southern sky. It’s shaped as a bright knot with diffuse emission trailing behind it, suggesting this cloud is traveling toward the disk of the galaxy.

From simulations of cloud infall, we expect that any cloud that travels more than ~33,000 light-years through the galactic halo would be stripped of its neutral gas by the hot interstellar medium. Surprisingly, though the Smith cloud has traveled more than that distance, it retains its gas — which means that something must be protecting it. But what?

The relative nearness of the Smith cloud and its large size make it a convenient target to search for the answer. The cloud spans an enormous angular diameter of 10–12 degrees, or about 20 times the diameter of the Moon! By looking through this diffuse cloud at objects behind it, we can learn more about its properties — and in particular, about its magnetic field.

Rotation measures (RMs) — measurements of how much the cloud caused the background source’s polarization to rotate — for distant radio sources near or behind the Smith cloud. Previous data is shown in cyan and magenta; the authors’ new data is shown in blue and red. Blue and cyan indicate negative RMs (the magnetic field points away from the observer); red and magenta indicate positive RMs (magnetic field points toward the observer). [Betti et al. 2019]

Dragging a Magnetic Field

Led by student Sarah Betti (Haverford College; University of Massachusetts), a team of scientists obtained Jansky Very Large Array observations of 1,105 distant radio sources behind and next to the Smith cloud.

NRAO/Karl V Jansky Expanded Very Large Array, on the Plains of San Agustin fifty miles west of Socorro, NM, USA, at an elevation of 6970 ft (2124 m)

By measuring how the polarizations of these sources rotate as a result of passing through the magnetic field of the cloud, Betti and collaborators were able to map out the strength and geometry of the cloud’s field.

The Smith cloud’s magnetic field, the authors find, appears to be draped over the ionized gas and compressed at the head of the cloud. This geometry is consistent with a picture in which the cloud has swept up the ambient field as it plunges toward the plane of the galaxy, compressing it ahead of the cloud and dragging it along with it.

A Powerful Shield

Can this scenario explain the surprising persistence of the cloud? Perhaps! Past studies have shown that such magnetic field accumulation could be strong enough to shield a cloud’s neutral gas from the hot interstellar medium, protecting it from being stripped as the cloud passes through the halo.

Now that we have detailed observations of the Smith cloud’s magnetic field, careful future modeling can provide tests of whether the field strength is enough to explain how the cloud has survived its travels.


“Constraining the Magnetic Field of the Smith High-velocity Cloud Using Faraday Rotation,” S. K. Betti et al 2019 ApJ 871 215.

See the full article here .


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