Effect of heat treatments and coatings on the outgassing rate of stainless steel chambers

Mamun, Abdullah Al; Elmustafa, A. A.; Stutzman, Marcy; Adderley, P.; Poelker, M.

doi:10.1116/1.4853795

Cited by 29 publications

(19 citation statements)

References 41 publications

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“…The photogun vacuum chamber is made of 304L stainless steel 0.5 cm thick. Prior to assembly, the empty chamber was vacuum baked at 400°C for 100 hours to reduce outgassing from the chamber walls [27]. The resulting outgassing rate was ∼2 × 10 −13 Torr l=s=cm 2 measured using a spinning rotor gauge.…”

Section: A Photogunmentioning

confidence: 99%

Compact −300 kV dc inverted insulator photogun with biased anode and alkali-antimonide photocathode

Hernandez‐Garcia

Adderley

Bullard

et al. 2019

Phys. Rev. Accel. Beams

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This contribution describes the latest milestones of a multiyear program to build and operate a compact −300 kV dc high voltage photogun with inverted insulator geometry and alkali-antimonide photocathodes. Photocathode thermal emittance measurements and quantum efficiency charge lifetime measurements at average current up to 4.5 mA are presented, as well as an innovative implementation of ion generation and tracking simulations to explain the benefits of a biased anode to repel beam line ions from the anodecathode gap, to dramatically improve the operating lifetime of the photogun and eliminate the occurrence of micro-arc discharges.

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Section: A Photogunmentioning

confidence: 99%

Compact −300 kV dc inverted insulator photogun with biased anode and alkali-antimonide photocathode

Hernandez‐Garcia

Adderley

Bullard

et al. 2019

Phys. Rev. Accel. Beams

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“…16 to calculate the Fourier number. The Fourier number is very sensitive to E D , and it is worth noting that choosing E D = 0.65 eV from Mamun et al ., 12 for example, decreases the Fourier numbers in Table II by more than a factor of two. We use the flange thickness for d .…”

Section: Resultsmentioning

confidence: 99%

Investigations of medium-temperature heat treatments to achieve low outgassing rates in stainless steel ultrahigh vacuum chambers

Sefa

Fedchak

Scherschligt

2017

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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The authors investigated the outgassing rates and fluxes of vacuum chambers constructed from common 304L stainless steel vacuum components and subjected to heat treatments. Our goal was to obtain H2 outgassing flux on the order of 10−11 Pa l s−1cm−2 or better from standard stainless steel vacuum components readily available from a variety of manufacturers. The authors found that a medium-temperature bake in the range of 400 to 450°C, performed with the interior of the chamber under vacuum, was sufficient to produce the desired outgassing flux. The authors also found that identical vacuum components baked in air at the same temperature for the same amount of time did not produce the same low outgassing flux. In that case, the H2 outgassing flux was lower than that of a stainless-steel chamber with no heat treatment, but was still approximately 1 order of magnitude higher than that of the medium-temperature vacuum-bake. Additionally, the authors took the chamber that was subjected to the medium-temperature vacuum heat treatment and performed a 24-h air bake at 430°C. This additional heat treatment lowered the outgassing rate by nearly a factor of two, which strongly suggests that the air-bake created an oxide layer which reduced the hydrogen recombination rate on the surface. [http://dx.doi.org/10.1116/1.4983211]

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“…We provide an overview of such treatments below; for more detail, the reader is encouraged to consult various texts on the subject 6—8 . For untreated 300 series stainless steel, the atomic hydrogen concentration is on the order of 2 ×10 19 cm −3 , corresponding to an H 2 equivalent pressure of roughly 4.1 ×10 4 Pa at 23 °C (approximately 4/10 of an atmosphere) 9 . In discussing gas evolution from materials, one often distinguishes outgassing due to gas dissolved within the material (absorbed gas) from desorption of gas adsorbed on the material surface.…”

Section: Theory Of Degassingmentioning

confidence: 99%

Vacuum furnace for degassing stainless-steel vacuum components

Fedchak

Scherschligt

Barker

et al. 2018

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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Ultra-high vacuum systems must often be constructed of materials with ultra-low outgassing rates to achieve pressure of 10 Pa and below. Any component placed into the ultra-high vacuum system must also be constructed of materials with ultra-low outgassing rates. Baking stainless steel vacuum components to a temperature range of 400 °C to 450 °C while under vacuum is an effective method to reduce the outgassing rate of vacuum components for use in ultra-high vacuum systems. The design, construction, and operation of a vacuum furnace capable of baking vacuum components to a temperature of 450° C while maintaining a pressure of 10 Pa or lower is described. The furnace has been used for extended bakes at 450 °C while maintaining pressures below 10 Pa. As an example, we obtained an outgassing rate of 1.2 × 10 Pa L s for a gate valve baked for 20 days at a temperature of 420 °C.

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Effect of heat treatments and coatings on the outgassing rate of stainless steel chambers

Cited by 29 publications

References 41 publications

Compact −300 kV dc inverted insulator photogun with biased anode and alkali-antimonide photocathode

Compact −300 kV dc inverted insulator photogun with biased anode and alkali-antimonide photocathode

Investigations of medium-temperature heat treatments to achieve low outgassing rates in stainless steel ultrahigh vacuum chambers

Vacuum furnace for degassing stainless-steel vacuum components

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