heic0209 — Photo Release

A glimpse into the heart of a dying star

18 July 2002

An image taken with the NASA/ESA Hubble Space Telescope shows one of the most unusually long planetary nebulae found so far. Scientists think planetary nebulae hold the key to understanding how the Universe became enriched with heavier elements so they study them intensively. It is not well-understood how a perfectly round star can turn into such an unusual-looking nebula.

Stars are large recycling factories. Over their lifetimes of millions of years they process huge amounts of the lighter elements (mostly hydrogen and helium) into heavier ones (such as carbon, nitrogen and oxygen). These heavier elements are then dispersed into the surrounding space when the stars peel off their atmospheres to form planetary nebulae. In turn, the heavier elements may become part of other stars or end up in planetary systems like our own Solar System. This dispersion process is therefore one of the most important in the Universe and can tell us something about our own origins.

Hubble image of Henize 3-401

This image, taken with the NASA/ESA Hubble Space Telescope, shows the young planetary nebula Henize 3-401. Hubble's extraordinary vision reveals that it is one of the most elongated planetary nebulae found so far. The image shows two very long cylindrical outflows with intricate thread-like structures and tattered ends. In this image, we are seeing the central star responsible for the beautiful display in the nebula for the first time.

Although planetary nebulae exist in many different shapes they are often elongated, or as astronomers call it, 'bipolar'. Although astronomers agree on the terminology, they disagree on how these nebulae become so elongated. Some claim that a second star, a companion orbiting around the central star, is needed to create the jet-like streamers of gas. Others think that strong magnetic fields are capable of funnelling the gas into the long outflows.

Henize 3-401 is an interesting astronomical object since astronomers can peer directly into the brew of different elements created in the witch's cauldron that is a star's core. During this brew, stars form complex organic molecules that may be some of the molecular building blocks of life.

Henize 3-401 is currently passing through a phase that is very short, in astronomical terms, and there are not very many similar objects around for similar study. It will take only a few thousand years for the central star to exhaust its nuclear fuel and become a cooling, fading white dwarf.

Nebula clings to its secrets

European astronomers have combined Hubble images with observations from several other telescopes, among them ESA's Infrared Space Observatory (ISO) and the International Ultraviolet Explorer (IUE), but it is proving difficult to unveil the origin of this nebula. As Pedro Garcma-Lario from the ESA ISO Data Centre in Villafranca, Spain, says: 'We are studying stars at a crucial moment in their life - as they die. Our ultimate goal is to find out exactly how the dying stars spread these huge amounts of processed material throughout the Universe. How can a perfectly round star undergo a rapid metamorphosis to become such an elongated object as Henize 3-401? These are key questions to answer if we want to find out how our Milky Way evolves chemically.'

Despite the ongoing efforts of Garcma-Lario and others studying Henize 3-401, the detailed nature and origin of this nebula remain deep mysteries.

Henize 3-401 is located in the constellation of Carina (the Keel) at an approximate distance of 10 000 light-years. This picture is composed of three exposures obtained with Hubble's Wide Field Planetary Camera 2 on 12 June 1997. The three exposures were taken through a wide orange filter (1200 seconds) shown in blue, a hydrogen-alpha filter (400 seconds) shown in red, and a singly ionised sulphur filter (1200 seconds) shown in green.


The Hubble Space Telescope project is an international cooperation between ESA and NASA.

The original Hubble image was obtained by R. Sahai (Jet Propulsion Laboratory, USA), V. Bujarrabal (Observatorio Astronomico, Spain), J. Trauger (Jet Propulsion Laboratory, USA), A. Zijlstra (University of Manchester Institute of Science and Technology, United Kingdom) and J. Alcolea (Centro Astronomico de Yebes, Spain).

The image processing for this image was done by Richard Hook and the Hubble European Space Agency Information Centre.

The International Ultraviolet Explorer (IUE) is the world's longest lived and one of the most productive satellites ever built. A joint ESA-NASA-UK project, it was launched in January 1978 and worked non-stop until switched off in September 1996.

The Infrared Space Observatory (ISO) was the most sensitive infrared satellite ever launched. It studied the dusty regions of the Universe, something visible light telescopes are unable to do. Launched in 1995, it operated from November 1995 to May 1998.


More info about Henize 3-401


Pedro Garcma-Lario
ESA ISO Data Centre
Villafranca, Spain
Phone: +34 91 813 1389
E-mail: pedro.garcia.lario@esa.int

Lars Lindberg Christensen
Hubble European Space Agency Information Centre
Garching, Germany
Phone: +49-89-3200-6306 (089 within Germany)
Cellular (24 hr): +49-173-3872-621 (0173 in Germany)
E-mail: lars@eso.org

About the Release

Release No.:heic0209


A glimpse into the heart of a dying star
A glimpse into the heart of a dying star

Print Layouts

A glimpse into the heart of a dying star
A glimpse into the heart of a dying star


r.titlePDF File
60.1 KB
r.titleWord File
238.0 KB

Also see our

Privacy policy Accelerated by CDN77