Protostars in Perseus: Outflow-induced fragmentation

We present new far-infrared, submillimeter, and millimeter images of candid ate protostars in the Perseus molecular cloud complex: L1448N/IRS3, L1448C, and IRAS 03282+3035. L1448N/IRS3 is now known to comprise three separate m illimeter-continuum sources: L1448N(A) and L1448N(B), which form a close (7 " separation) binary, and L1448NW, similar to 20" to the northwest. The new maps presented here include 12, 25, 60, and 100 mu m high-resolution-proce ssed (HIRES-processed) IRAS images, 450 and 800 mu m maps from the 15 m Jam es Clerk Maxwell Telescope (JCMT), and a 1300 mu m bolometer array map of t he L1448 sources from the IRAM 30 m telescope. We present new spectral ener gy distributions (SEDs) for L1448C, L1448NW, and IRAS 03282. We confirm the Class 0 status of L1448C, L1448N(A), L1448N(B), and IRAS 03282. There is e vidence for a modest compact "disk" component in L1448C (similar to 0.004 M .). We deduce that a 1.4 M. circumbinary envelope surrounds the similar to 1 M. protobinary system, L1448N(A)+L1448N(B). The dust emission from IRAS 0 3282 is found to be somewhat extended, on scales of 0.015-0.03 pc. Extensiv e HIRES-processed point-source modeling of the 100 mu m emission associated with IRAS 03282 reveals an elongated structure along a north-south axis, s patially coincident with the previously mapped NH3 (1, 1) emission. Both th e 100 mu m dust emission and the ammonia trace the dense core from which IR AS 03282 is currently forming. We identify two distinct outflows in L1448N for the first time, one powered by L1448N(A) and the other by L1448N(B). A bridge of dust emission linking L1448C to L1448N is clearly evident in our HIRES-processed 100 mu m map. This dust structure traces the surface where the L1448C and L1448N(A) outflows collide. Two new 100 mu m emission peaks are found, one coinciding with HH 197, the other with an H-2 bow-shock feat ure. Both 100 mu m peaks are located at positions where the blueshifted L14 48C jet is deflected. The luminosity radiated by the dust emission bridge i s similar to 6.5 L., which is a new estimate for the instantaneous L1448C o utflow mechanical luminosity. We find L-mech/L-bol greater than or equal to 50% for all of the confirmed Perseus Class 0 sources for which outflow dat a are available from the literature. Thus, we confirm a high L-mech/L-bol a s a new distinguishing characteristic of Class 0 outflows. The dynamical ti mes for the L1448N(B) and L1448C outflows have been revised upward to 13,00 0 and 32,000 yr, respectively, based on the identification of L1448N(B) as the powering source of HH 196 and of L1448C as the driving source of HH 267 . As a consequence, the outflow dynamical times now agree with the typical ages inferred for Class 0 sources. There is strong evidence for outflow-ind uced star formation in the L1448 cloud. Being older, the L1448C outflow has disrupted and fragmented the core that is now forming the younger L1448N(A )+L1448N(B) protobinary. The interaction of the L1448N(A) and L1448N(B) out flows, in turn, may have produced the L1448NW condensation.