Titanium carbide nanocrystals in circumstellar environments

G von Helden; ACGM Tielens; D van Heijnsbergen; MA Duncan; S Hony; LBFM Waters; G. Meijer

Titanium carbide nanocrystals in circumstellar environments

G von Helden^*, ACGM Tielens, D van Heijnsbergen, MA Duncan, S Hony, LBFM Waters, G. Meijer

^*Corresponding author for this work

Kapteyn Astronomical Institute

Research output: Contribution to journal › Article › Academic › peer-review

127 Citations (Scopus)

Abstract

Meteorites contain micrometer-sized graphite grains with embedded titanium carbide grains. Although isotopic analysis identifies asymptotic giant branch stars as the birth sites of these grains, there is no direct observational identification of these grains in astronomical sources. We report that infrared wavelength spectra of gas-phase titanium carbide nanocrystals derived in the laboratory show a prominent feature at a wavelength of 20.1 micrometers, which compares well to a similar feature in observed spectra of postasymptotic giant branch stars. It is concluded that titanium carbide forms during a short (approximately 100 years) phase of catastrophic mass Loss (>0.001 solar masses per year) in dying, Low-mass stars.

Original language	English
Pages (from-to)	313-316
Number of pages	6
Journal	Science
Volume	288
Issue number	5464
Publication status	Published - 14-Apr-2000

Keywords

RICH PROTOPLANETARY NEBULAE
MASS-LOSS
EMISSION
STARS
EVOLUTION
GRAPHITE
SHELLS
SIS2
DUST

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@article{6ad2bf692fe54b5eb66e3cd8bdbc9297,

title = "Titanium carbide nanocrystals in circumstellar environments",

abstract = "Meteorites contain micrometer-sized graphite grains with embedded titanium carbide grains. Although isotopic analysis identifies asymptotic giant branch stars as the birth sites of these grains, there is no direct observational identification of these grains in astronomical sources. We report that infrared wavelength spectra of gas-phase titanium carbide nanocrystals derived in the laboratory show a prominent feature at a wavelength of 20.1 micrometers, which compares well to a similar feature in observed spectra of postasymptotic giant branch stars. It is concluded that titanium carbide forms during a short (approximately 100 years) phase of catastrophic mass Loss (>0.001 solar masses per year) in dying, Low-mass stars.",

keywords = "RICH PROTOPLANETARY NEBULAE, MASS-LOSS, EMISSION, STARS, EVOLUTION, GRAPHITE, SHELLS, SIS2, DUST",

author = "{von Helden}, G and ACGM Tielens and {van Heijnsbergen}, D and MA Duncan and S Hony and LBFM Waters and G. Meijer",

year = "2000",

month = apr,

day = "14",

language = "English",

volume = "288",

pages = "313--316",

journal = "Science",

issn = "0036-8075",

publisher = "AMER ASSOC ADVANCEMENT SCIENCE",

number = "5464",

}

TY - JOUR

T1 - Titanium carbide nanocrystals in circumstellar environments

AU - von Helden, G

AU - Tielens, ACGM

AU - van Heijnsbergen, D

AU - Duncan, MA

AU - Hony, S

AU - Waters, LBFM

AU - Meijer, G.

PY - 2000/4/14

Y1 - 2000/4/14

N2 - Meteorites contain micrometer-sized graphite grains with embedded titanium carbide grains. Although isotopic analysis identifies asymptotic giant branch stars as the birth sites of these grains, there is no direct observational identification of these grains in astronomical sources. We report that infrared wavelength spectra of gas-phase titanium carbide nanocrystals derived in the laboratory show a prominent feature at a wavelength of 20.1 micrometers, which compares well to a similar feature in observed spectra of postasymptotic giant branch stars. It is concluded that titanium carbide forms during a short (approximately 100 years) phase of catastrophic mass Loss (>0.001 solar masses per year) in dying, Low-mass stars.

AB - Meteorites contain micrometer-sized graphite grains with embedded titanium carbide grains. Although isotopic analysis identifies asymptotic giant branch stars as the birth sites of these grains, there is no direct observational identification of these grains in astronomical sources. We report that infrared wavelength spectra of gas-phase titanium carbide nanocrystals derived in the laboratory show a prominent feature at a wavelength of 20.1 micrometers, which compares well to a similar feature in observed spectra of postasymptotic giant branch stars. It is concluded that titanium carbide forms during a short (approximately 100 years) phase of catastrophic mass Loss (>0.001 solar masses per year) in dying, Low-mass stars.

KW - RICH PROTOPLANETARY NEBULAE

KW - MASS-LOSS

KW - EMISSION

KW - STARS

KW - EVOLUTION

KW - GRAPHITE

KW - SHELLS

KW - SIS2

KW - DUST

M3 - Article

SN - 0036-8075

VL - 288

SP - 313

EP - 316

JO - Science

JF - Science

IS - 5464

ER -

Titanium carbide nanocrystals in circumstellar environments

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