Professor James Binney FRS

Improved distances and ages for stars common to TGAS and RAVE

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 477:4 (2018) 5279-5300

Authors:

Paul J McMillan, Georges Kordopatis, Andrea Kunder, James Binney, Jennifer Wojno, Tomaž Zwitter, Matthias Steinmetz, Joss Bland-Hawthorn, Brad K Gibson, Gerard Gilmore, Eva K Grebel, Amina Helmi, Ulisse Munari, Julio F Navarro, Quentin A Parker, George Seabroke, Fred Watson, Rosemary FG Wyse

Is the Milky Way still breathing? RAVE–Gaia streaming motions

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 475:2 (2018) 2679-2696

Authors:

I Carrillo, I Minchev, G Kordopatis, M Steinmetz, J Binney, F Anders, O Bienaymé, J Bland-Hawthorn, B Famaey, KC Freeman, G Gilmore, BK Gibson, EK Grebel, A Helmi, A Just, A Kunder, P McMillan, G Monari, U Munari, J Navarro, QA Parker, W Reid, G Seabroke, S Sharma, A Siebert, F Watson, J Wojno, RFG Wyse, T Zwitter

Self-consistent modelling of our Galaxy with Gaia data

Proceedings of the International Astronomical Union Cambridge University Press 12 (2018) 111-118

Abstract:

Galaxy models are fundamental to exploiting surveys of our Galaxy. There is now a significant body of work on axisymmetric models. A model can be defined by giving the DF of each major class of stars and of dark matter. Then the self-consistent gravitational potential is determined. Other modelling techniques are briefly considered before an overview of some early work on non-axisymmetric models.

A theoretical explanation for the Central Molecular Zone asymmetry

Monthly Notices of the Royal Astronomical Society Oxford University Press 475:2 (2017) 2383-2402

Authors:

MC Sormani, R Tress, Matthew Ridley, SCO Glover, RS Klessen, James Binney, Stephen Magorrian, R Smith

Abstract:

It has been known for more than thirty years that the distribution of molecular gas in the innermost 300 parsecs of the Milky Way, the Central Molecular Zone, is strongly asymmetric. Indeed, approximately three quarters of molecular emission comes from positive longitudes, and only one quarter from negative longitudes. However, despite much theoretical effort, the origin of this asymmetry has remained a mystery. Here we show that the asymmetry can be neatly explained by unsteady flow of gas in a barred potential. We use high-resolution 3D hydrodynamical simulations coupled to a state-of-the-art chemical network. Despite the initial conditions and the bar potential being point-symmetric with respect to the Galactic Centre, asymmetries develop spontaneously due to the combination of a hydrodynamical instability known as the “wiggle instability” and the thermal instability. The observed asymmetry must be transient: observations made tens of megayears in the past or in the future would often show an asymmetry in the opposite sense. Fluctuations of amplitude comparable to the observed asymmetry occur for a large fraction of the time in our simulations, and suggest that the present is not an exceptional moment in the life of our Galaxy.

Orbital tori for non-axisymmetric galaxies

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2017)