An H-alpha nuclear spiral structure in the E0 active galaxy Arp102B

TL;DR

This paper reports the discovery of a two-armed H-alpha nuclear spiral in Arp102B, likely caused by jet-cloud interactions rather than gas inflow, with implications for understanding active galaxy nuclei dynamics.

Contribution

It presents the first detailed observation of a nuclear spiral in Arp102B and suggests a jet-cloud interaction as the origin, contrasting previous inflow hypotheses.

Findings

Nuclear spiral extends up to 1 kpc from the nucleus.

Radio jet correlates with the eastern spiral arm.

Jet is likely relativistic with a speed of about 0.45c.

Abstract

We report the discovery of a two-armed mini-spiral structure within the inner kiloparsec of the E0 LINER/Seyfert 1 galaxy Arp102B. The arms are observed in H-alpha emission and located East and West of the nucleus, extending up to about 1 kpc from it. We use narrow-band imaging from the Hubble Space Telescope Advanced Camera for Surveys, in combination with archival VLA radio images at 3.6 and 6 cm to investigate the origin of the nuclear spiral. From the H-alpha luminosity of the spiral, we obtain an ionized gas mass of the order of one million solar masses. One possibility is that the nuclear spiral represents a gas inflow triggered by a recent accretion event which has replenished the accretion disk, giving rise to the double-peaked emission-line profiles characteristic of Arp102B. However, the radio images show a one-sided curved jet which correlates with the eastern spiral arm observed in the H-alpha image. A published milliarcsecond radio image also shows one-sided structure at position angle about 40 degrees, approximately aligned with the inner part of the eastern spiral arm. The absence of a radio counter-part to the western spiral arm is tentatively interpreted as indicating that the jet is relativistic, with an estimated speed of 0.45c. Estimates of the jet kinetic energy and the ionizing luminosity of the active nucleus indicate that both are capable of ionizing the gas along the spiral arms. We conclude that, although the gas in the nuclear region may have originated in an accretion event, the mini-spiral is most likely the result of a jet-cloud interaction rather than an inflowing stream.