Astronomy & Astrophysics

Table of contents

A&A 455, 903-921 (2006)
DOI: 10.1051/0004-6361:20065084

ACIS-I observations of NGC 2264. Membership and X-ray properties of PMS stars

E. Flaccomio, G. Micela and S. Sciortino

INAF - Osservatorio Astronomico di Palermo Giuseppe S. Vaiana, Palazzo dei Normanni, 90134 Palermo, Italy
e-mail: [ettoref;giusi;sciorti]@astropa.inaf.it

(Received 24 February 2006 / Accepted 5 April 2006 )

Abstract
Aims.This paper's goal is to improve the member census of the NGC 2264 star-forming region and study the origin of X-ray activity in young PMS stars.
Methods.We analyze a deep, 100 ks long, Chandra ACIS observation covering a $17'\times17'$ field in NGC 2264. The preferential detection in X-rays of low-mass PMS stars gives strong indications of their membership. We study X-ray activity as a function of stellar and circumstellar characteristics by correlating the X-ray luminosities, temperatures, and absorptions with optical and near-infrared data from the literature.
Results.We detect 420 X-ray point sources. Optical and NIR counterparts are found in the literature for 85% of the sources. We argue that more than 90% of these counterparts are NGC 2264 members, thereby significantly increasing the known low-mass cluster population by about 100 objects. Among the sources without counterpart, about 50% are probably associated with members, several of which we expect to be previously unknown protostellar objects. With regard to activity we confirm several previous findings: X-ray luminosity is related to stellar mass, although with a large scatter; $L_{\rm X}/L_{\rm bol}$ is close to, but almost invariably below, the saturation level, 10^-3, especially when considering the quiescent X-ray emission. A comparison between CTTS and WTTS shows several differences: CTTS have, at any given mass, activity levels that are both lower and more scattered than WTTS; emission from CTTS may also be more time variable and is on average slightly harder than for WTTS. However, we find evidence in some CTTS of extremely cool, ${\sim}0.1{-}0.2$ keV, plasma which we speculate is heated by accretion shocks.
Conclusions.Activity in low-mass PMS stars, while generally similar to that of saturated MS stars, may be significantly affected by mass accretion in several ways: accretion is probably responsible for very soft X-ray emission directly produced in the accretion shock; it may reduce the average energy output of solar-like coronae, at the same time making them hotter and more dynamic. We briefly speculate on a physical scenario that can explain these observations.

Key words: stars: activity -- stars: coronae -- stars: pre-main sequence -- open clusters and associations: individual: NGC 2264 -- X-rays: stars