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Zerodur

Zerodur is a lithium-aluminosilicate glass-ceramic manufactured by Schott AG. Zerodur has a near zero coefficient of thermal expansion (CTE), and is used for high-precision applications in telescope optics, microlithography machines and inertial navigation systems.

Manufacturing process

Zerodur is produced in a two-step process involving melting and ceramization. Depending on the size of the blanks, each step can take several months.[2]

First, raw materials including main components of lithium oxide (Li2O), alumina (Al2O3), and silica (SiO2) are melted at high temperatures of around 1600 °C, poured into molds, and annealed in a controlled cooling process that relieves internal stresses that develop during forming.[3][4] Then the glass undergoes a ceramization process involving controlled volume crystallization, which creates high-quartz nano-crystallites of 30 nm to 50 nm.[2] The negative CTE of the crystals compensates for the positive CTE of the residual glass matrix, which gives Zerodur its near zero thermal expansion.[4]

Applications

The main applications for Zerodur include telescope optics in astronomy[5] and space applications,[6] lithography machines for microchips and displays,[7] and inertial measurements systems for navigation.[8][9]

In astronomy, it is used for mirror substrates in large telescopes such as the Hobby-Eberly Telescope,[10] the Keck I and Keck II telescopes,[11] the Gran Telescopio Canarias,[12] the Devasthal Optical Telescope,[13] the European Southern Observatory's 8.2 m Very Large Telescope,[14] and the 39 m Extremely Large Telescope.[15] It also has been used for the primary mirror of SOFIA's airborne telescope.[16]

ASA also produces some telescopes with zerodur.[17]

In space, it has been used for the imager in Meteosat Earth observation satellites,[18] and for the optical bench in the LISA Pathfinder mission.[19]

In microlithography, Zerodur is used in wafer steppers and scanner machines for precise and reproducible wafer positioning.[20][21] It is also used as a component in refractive optics for photolithography.[22]

In inertial measurement units, Zerodur is used in ring laser gyroscopes.[23]

Properties

Zerodur has both an amorphous (vitreous) component and a crystalline component. Its most important properties[24] are:

  • The material exhibits a particularly low thermal expansion, with a mean value of 0 ± 0.007×10−6 K−1 within the temperature range of 0 to 50 °C.[25]
  • High 3D homogeneity[25] with few inclusions, bubbles and internal stria.
  • Hardness similar to that of borosilicate glass.
  • High affinity for coatings.
  • Low helium permeability.
  • Non-porous.
  • Good chemical stability.
  • Fracture toughness approximately 0.9 MPa·m1/2.[26][27]

Physical properties

  • Dispersion: (nF − nC) = 0.00967
  • Density: 2.53 g/cm3 at 25 °C
  • Young's modulus: 9.1 Pa
  • Poisson ratio: 0.24
  • Specific heat capacity at 25 °C: 0.196 cal/(g·K) = 0.82 J/(g·K)
  • Coefficient of thermal expansion (20 °C to 300 °C) : 0.05 ± 0.10/K
  • Thermal conductivity: at 20 °C: 1.46 W/(m·K)
  • Maximum application temperature: 600 °C
  • Impact resistance behavior is substantially similar to other glass[28]

History

Schott began developing glass-ceramics in the 1960s lead by Jürgen Petzoldt, in response to demand for low expansion glass ceramics for telescopes.

In 1966, Hans Elsässer, the founding director of the Max Planck Institute for Astronomy (MPIA), asked the company if it could produce large castings of almost 4 meters using low-expansion glass-ceramic for telescope mirror substrates. In 1969, the MPIA ordered a 3.6 m mirror blank, along with ten smaller mirror substrates. The mirrors were delivered by late 1975,[29] and went into operation in 1984 in a telescope at the Calar Alto Observatory in Spain. Further orders for mirror blanks followed.[30]

See also

External links

References

  1. Secondary Mirror of ELT Successfully Cast - Largest convex mirror blank ever created www.eso.org, retrieved 22 May 2017^
  2. Stephen Sokach. ZERODUR: The Highly Technical Glass-Ceramic techbriefs.com, July 2020, retrieved 13 February 2025^
  3. Glass-ceramic production is fit for the future GlassOnWeb, 23 February 2017, retrieved 13 February 2025^
  4. George J. Gardopee, Da-Wun Shen. Lightweight Zerodur Mirror Technology The Perkin-Elmer Corporation, October 1982, retrieved 13 February 2025^
  5. Thorsten Döhring. 4th International Symposium on Advanced Optical Manufacturing and Testing Technologies: Large Mirrors and Telescopes May 2019, retrieved 10 May 2024^
  6. Antoine Carré. Comprehensive review of the effects of ionizing radiations on the ZERODUR® glass ceramic Journal of Astronomical Telescopes, Instruments, and Systems, May 2023^
  7. SCHOTT Strengthens Glass Substrate Portfolio Printed Electronics Now, September 29, 2023^
  8. Stephen Sokach. ZERODUR: The Highly Technical Glass-Ceramic Tech Briefs, July 2020, retrieved 10 May 2024^
  9. Zerodur Mindrum Precision, retrieved 10 May 2024^
  10. Hobby-Eberly Telescope mcdonaldobservatory.org, retrieved 2024-07-12^
  11. A Mirror's Perfect Reflection W.M. Keck Observatory, 28 May 2010, retrieved 10 May 2024^
  12. Description of the GTC Gran Telescopio CANARIAS, retrieved 10 May 2024^
  13. 3.6 m DOT Telescope ARIES, retrieved July 7, 2024^
  14. Very Large Telescope ESO, retrieved 10 May 2024^
  15. Mirrors and Optical Design ESO, retrieved 10 May 2024^
  16. Alfred Krabbe. Airborne Telescope Systems June 2000, retrieved 10 May 2024^
  17. ASA 2.5-Meter Telescope AZ2500 Observatory Solutions, retrieved 2025-01-08^
  18. MTG (Meteosat Third Generation) - eoPortal www.eoportal.org, retrieved 2024-07-12^
  19. LISA Technology Package Optical Bench Interferometer During Calibration ESA, retrieved 10 May 2024^
  20. Peter Hartmann. SCHOTT – Ultra low expansion glass ceramic ZERODUR Max-Planck-Institut für Astronomie, retrieved 10 May 2024^
  21. Ralf Jedamzik. Optical Microlithography XXVII 2014^
  22. Ina Mitra. ZERODUR: a glass-ceramic material enabling optical technologies Optical Materials Express, September 2022, retrieved 10 May 2024^
  23. Linda R. Pinckney. Encyclopedia of Physical Science and Technology 2003, retrieved 10 May 2024^
  24. Technical Details ZERODUR® schott.com, retrieved 6 September 2024^
  25. Peter Hartmann, Ralf Jedamzik, Antoine Carré, Janina Krieg, Thomas Westerhoff. Glass ceramic ZERODUR®: Even closer to zero thermal expansion: A review, part 2 Journal of Astronomical Telescopes, Instruments, and Systems, 24 March 2006^
  26. Michael J Viens. Fracture Toughness and Crack Growth of Zerodur NASA Technical Memorandum 4185, NASA, April 1990, retrieved 6 September 2024^
  27. P. Hartmann. ZERODUR - Deterministic Approach for Strength Design Optical Engineering, NASA, 18 December 2012, retrieved 11 September 2013^
  28. H Senf. A study of Damage during Impact in Zerodur Le Journal de Physique IV, 1997, retrieved 31 August 2011^
  29. Wolfgang Pannhorst. Low Thermal Expansion Glass Ceramics Springer, 1995^
  30. Dietrich Lemke. Im Himmel über Heidelberg - 50 Jahre Max-Planck-Institut für Astronomie in Heidelberg (1969 – 2019)^