Refractory metals revolutionizing the lighting technology: A historical review

P. Schade, H. M. Ortner, Ivica Smid

Research output: Contribution to journalReview article

4 Citations (Scopus)

Abstract

From a historical point of view, the development of the PM processing steps and tools "for making tungsten ductile" by William D. Coolidge in 1909 marks the breakthrough for the use of tungsten filaments in the lighting industry and the beginning of the industrial era of Powder Metallurgy. However, other refractory metals, osmium and tantalum, had been considered useful lamp filaments prior to tungsten. Other technological concepts as, e.g. the gas mantle lamp of Auer von Welsbach, are still in limited use today. The significance of the Coolidge process is shortly outlined for the production of ductile tungsten. In addition some further important accompanying discoveries and inventions will be mentioned: cemented carbides and tungsten heavy metals. The scientific importance of the potassium bubbles as the strongest pinning points at highest temperatures against the movement of dislocations and grain boundaries will be highlighted shortly. It is in our opinion, the most ingenious "dispersoid" ever developed by mankind: non-effective at lower temperatures and thus not interfering with the wire drawing and coiling processes but very effective as dispersoid at the operating temperatures of incandescent lamps as mentioned above. Considering geometrical dimensions, the microstructural features of the finest wires with diameters in the single micrometer domain and the corresponding fabrication of diamond dies, necessary for the deformation of wires, also represent precursors of today's nanotechnology and micromachining. Some further important points for the fabrication of incandescent lamps are mentioned: the introduction of the Langmuir sheath and the significance of molybdenum for the lighting industry. Finally the ban of incandescent lamps by the European Union is outlined and a brief overview of modern means of lighting is given. Compact fluorescent lamps and high intensity discharge lamps and the use of refractory metals in the LED-production end this brief overview on modern lighting and no device is without a refractory metal.

Original languageEnglish (US)
Pages (from-to)23-30
Number of pages8
JournalInternational Journal of Refractory Metals and Hard Materials
Volume50
DOIs
StatePublished - Jan 1 2015

Fingerprint

Refractory metals
Tungsten
Incandescent lamps
Lighting
Filaments (lamp)
Wire
Tantalum
Discharge lamps
Wire drawing
Osmium
Fabrication
Fluorescent lamps
Diamond
Molybdenum
Micromachining
Patents and inventions
Powder metallurgy
Heavy Metals
Dislocations (crystals)
Electric lamps

All Science Journal Classification (ASJC) codes

  • Ceramics and Composites
  • Mechanics of Materials
  • Mechanical Engineering
  • Metals and Alloys
  • Materials Chemistry

Cite this

@article{392fd4d789d94d51b57cf5e9038aa6a9,
title = "Refractory metals revolutionizing the lighting technology: A historical review",
abstract = "From a historical point of view, the development of the PM processing steps and tools {"}for making tungsten ductile{"} by William D. Coolidge in 1909 marks the breakthrough for the use of tungsten filaments in the lighting industry and the beginning of the industrial era of Powder Metallurgy. However, other refractory metals, osmium and tantalum, had been considered useful lamp filaments prior to tungsten. Other technological concepts as, e.g. the gas mantle lamp of Auer von Welsbach, are still in limited use today. The significance of the Coolidge process is shortly outlined for the production of ductile tungsten. In addition some further important accompanying discoveries and inventions will be mentioned: cemented carbides and tungsten heavy metals. The scientific importance of the potassium bubbles as the strongest pinning points at highest temperatures against the movement of dislocations and grain boundaries will be highlighted shortly. It is in our opinion, the most ingenious {"}dispersoid{"} ever developed by mankind: non-effective at lower temperatures and thus not interfering with the wire drawing and coiling processes but very effective as dispersoid at the operating temperatures of incandescent lamps as mentioned above. Considering geometrical dimensions, the microstructural features of the finest wires with diameters in the single micrometer domain and the corresponding fabrication of diamond dies, necessary for the deformation of wires, also represent precursors of today's nanotechnology and micromachining. Some further important points for the fabrication of incandescent lamps are mentioned: the introduction of the Langmuir sheath and the significance of molybdenum for the lighting industry. Finally the ban of incandescent lamps by the European Union is outlined and a brief overview of modern means of lighting is given. Compact fluorescent lamps and high intensity discharge lamps and the use of refractory metals in the LED-production end this brief overview on modern lighting and no device is without a refractory metal.",
author = "P. Schade and Ortner, {H. M.} and Ivica Smid",
year = "2015",
month = "1",
day = "1",
doi = "10.1016/j.ijrmhm.2014.11.002",
language = "English (US)",
volume = "50",
pages = "23--30",
journal = "International Journal of Refractory Metals and Hard Materials",
issn = "0958-0611",
publisher = "Elsevier BV",

}

Refractory metals revolutionizing the lighting technology : A historical review. / Schade, P.; Ortner, H. M.; Smid, Ivica.

In: International Journal of Refractory Metals and Hard Materials, Vol. 50, 01.01.2015, p. 23-30.

Research output: Contribution to journalReview article

TY - JOUR

T1 - Refractory metals revolutionizing the lighting technology

T2 - A historical review

AU - Schade, P.

AU - Ortner, H. M.

AU - Smid, Ivica

PY - 2015/1/1

Y1 - 2015/1/1

N2 - From a historical point of view, the development of the PM processing steps and tools "for making tungsten ductile" by William D. Coolidge in 1909 marks the breakthrough for the use of tungsten filaments in the lighting industry and the beginning of the industrial era of Powder Metallurgy. However, other refractory metals, osmium and tantalum, had been considered useful lamp filaments prior to tungsten. Other technological concepts as, e.g. the gas mantle lamp of Auer von Welsbach, are still in limited use today. The significance of the Coolidge process is shortly outlined for the production of ductile tungsten. In addition some further important accompanying discoveries and inventions will be mentioned: cemented carbides and tungsten heavy metals. The scientific importance of the potassium bubbles as the strongest pinning points at highest temperatures against the movement of dislocations and grain boundaries will be highlighted shortly. It is in our opinion, the most ingenious "dispersoid" ever developed by mankind: non-effective at lower temperatures and thus not interfering with the wire drawing and coiling processes but very effective as dispersoid at the operating temperatures of incandescent lamps as mentioned above. Considering geometrical dimensions, the microstructural features of the finest wires with diameters in the single micrometer domain and the corresponding fabrication of diamond dies, necessary for the deformation of wires, also represent precursors of today's nanotechnology and micromachining. Some further important points for the fabrication of incandescent lamps are mentioned: the introduction of the Langmuir sheath and the significance of molybdenum for the lighting industry. Finally the ban of incandescent lamps by the European Union is outlined and a brief overview of modern means of lighting is given. Compact fluorescent lamps and high intensity discharge lamps and the use of refractory metals in the LED-production end this brief overview on modern lighting and no device is without a refractory metal.

AB - From a historical point of view, the development of the PM processing steps and tools "for making tungsten ductile" by William D. Coolidge in 1909 marks the breakthrough for the use of tungsten filaments in the lighting industry and the beginning of the industrial era of Powder Metallurgy. However, other refractory metals, osmium and tantalum, had been considered useful lamp filaments prior to tungsten. Other technological concepts as, e.g. the gas mantle lamp of Auer von Welsbach, are still in limited use today. The significance of the Coolidge process is shortly outlined for the production of ductile tungsten. In addition some further important accompanying discoveries and inventions will be mentioned: cemented carbides and tungsten heavy metals. The scientific importance of the potassium bubbles as the strongest pinning points at highest temperatures against the movement of dislocations and grain boundaries will be highlighted shortly. It is in our opinion, the most ingenious "dispersoid" ever developed by mankind: non-effective at lower temperatures and thus not interfering with the wire drawing and coiling processes but very effective as dispersoid at the operating temperatures of incandescent lamps as mentioned above. Considering geometrical dimensions, the microstructural features of the finest wires with diameters in the single micrometer domain and the corresponding fabrication of diamond dies, necessary for the deformation of wires, also represent precursors of today's nanotechnology and micromachining. Some further important points for the fabrication of incandescent lamps are mentioned: the introduction of the Langmuir sheath and the significance of molybdenum for the lighting industry. Finally the ban of incandescent lamps by the European Union is outlined and a brief overview of modern means of lighting is given. Compact fluorescent lamps and high intensity discharge lamps and the use of refractory metals in the LED-production end this brief overview on modern lighting and no device is without a refractory metal.

UR - http://www.scopus.com/inward/record.url?scp=84912534872&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84912534872&partnerID=8YFLogxK

U2 - 10.1016/j.ijrmhm.2014.11.002

DO - 10.1016/j.ijrmhm.2014.11.002

M3 - Review article

AN - SCOPUS:84912534872

VL - 50

SP - 23

EP - 30

JO - International Journal of Refractory Metals and Hard Materials

JF - International Journal of Refractory Metals and Hard Materials

SN - 0958-0611

ER -