Apparent Faster-Than-Light Pulse Propagation in Interstellar Space: A new probe of the Interstellar Medium

TL;DR

This paper reports the first astrophysical observation of anomalous dispersion near the hydrogen resonance in interstellar space, causing pulses to appear faster than light without violating relativity, offering new insights into the interstellar medium.

Contribution

It presents the first direct astrophysical evidence of anomalous dispersion caused by neutral hydrogen, expanding the understanding of pulse propagation in the interstellar medium.

Findings

Clear evidence of anomalous dispersion observed in pulsar signals

Pulses near hydrogen resonance arrive earlier, indicating superluminal group velocity

Potential new method for studying neutral hydrogen in the Galaxy

Abstract

Radio pulsars emit regular bursts of radio radiation that propagate through the interstellar medium (ISM), the tenuous gas and plasma between the stars. Previously known dispersive properties of the ISM cause low frequency pulses to be delayed in time with respect to high frequency ones. This effect can be explained by the presence of free electrons in the medium. The ISM also contains neutral hydrogen which has a well known resonance at 1420.4 MHz. Electro-magnetic theory predicts that at such a resonance, the induced dispersive effects will be drastically different from those of the free electrons. Pulses traveling through a cloud of neutral hydrogen should undergo "anomalous dispersion", which causes the group velocity of the medium to be larger than the speed of light in vacuum. This superluminal group velocity causes pulses containing frequencies near the resonance to arrive earlier in time with respect to other pulses. Hence, these pulses appear to travel faster than light. This phenomenon is caused by an interplay between the time scales present in the pulse and the time scales present in the medium. Although counter-intuitive, it does not violate the laws of special relativity. Here, we present Arecibo observations of the radio pulsar PSR B1937+21 that show clear evidence of anomalous dispersion. Though this effect is known in laboratory physics, this is the first time it has been directly observed in an astrophysical context, and it has the potential to be a useful tool for studying the properties of neutral hydrogen in the Galaxy.