Vacuum Ultraviolet Radiation in Sources of Hyperthermal Atomic Oxygen. Photodestruction of Polytetrafluoroethylene (PTFE) and Teflon FEP for hdication of this Radiation

Skurat, V. E.; Samsonov, Pavel V; Nikiforov, A. P.

doi:10.1177/0954008304044104

Cited by 26 publications

(16 citation statements)

References 13 publications

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“…They found that, unlike the photolysis of PP and PE, CC bond generation is not a major process. They found CF n ( n = 1–3) in the ejecta, indicating that the polymer CC backbone undergoes scission, a process also observed by Skurat and Nikiforov 26. Ono et al estimated the quantum yield for atomic fluorine photolysis at 147 nm to be 0.0025.…”

Section: Introductionmentioning

confidence: 78%

Fluorine Plasma Treatments of Poly(propylene) Films, 2 – Modeling Reaction Mechanisms and Scaling

Yang

Strobel

Kirk

et al. 2010

Plasma Processes & Polymers

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IntroductionThe fluorination of the surface layers of hydrocarbon polymers modifies the wetting properties of the polymer by decreasing the surface energy and increasing hydrophobicity. [1][2][3] The fluorination process usually entails the removal of hydrogen from the hydrocarbon polymer backbone, forming an alkyl site, and the passivation of the alkyl site with a fluorine atom. [4] As most hydrocarbon polymers are heat sensitive, it is desirable for the fluorination to take place at low temperatures. As such, low-pressure, non-equilibrium plasmas are attractive options for this surface treatment.In low-pressure plasmas sustained in fluorine-containing feedstock gases, electron-impact reactions (mainly by dissociative excitation or attachment) produce

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Section: Introductionmentioning

confidence: 78%

Fluorine Plasma Treatments of Poly(propylene) Films, 2 – Modeling Reaction Mechanisms and Scaling

Yang

Strobel

Kirk

et al. 2010

Plasma Processes & Polymers

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“…Extensive efforts have been undertaken in both space environments and ground-based test facilities in order to unravel the erosion mechanisms of FEP Teflon. [31][32][33][34][35][36][37][38][39][40][41] FEP Teflon has strong absorption bands at VUV wavelengths. VUV radiation breaks C-C and C-F bonds and creates fragments that become volatile.…”

Section: Combined Effects Of Atomic Oxygen and Ultraviolet Lightmentioning

confidence: 99%

Mechanistic Studies of Atomic Oxygen Reactions with Polymers and Combined Effects with Vacuum Ultraviolet Light

Tagawa¹,

Minton²

2010

MRS Bull.

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This article focuses on mechanistic aspects of hyperthermal atomic oxygen reactions with polymers, which are the major contributor to material degradation in low Earth orbit. Due to the importance of well-controlled experiments in the understanding of the reaction mechanisms, ground-based experimental results obtained by a hyperthermal atomic oxygen beam generated by laser detonation facilities are mainly surveyed. Combined effects of atomic oxygen and vacuum ultraviolet (VUV) light on fluorinated polymers are also described. Such combined effects of hyperthermal atomic oxygen and VUV light are important not only from a fundamental point of view but also for engineering purposes (i.e., methodology for ground-based space environmental simulation). The VUV-sensitive polymers, poly(methyl methacrylate), and Teflonfluorinated ethylene-propylene do not show significant synergistic effects. Instead, the effect of combining atomic oxygen and VUV light produces erosion of the polymer that is the sum of the erosion caused by atomic oxygen and UV light acting individually. The experimental results suggest that material erosion in a complicated space environment may be quantitatively predicted if the erosion yields caused by the individual action of atomic oxygen and VUV light are known. sion energy, AO erodes many polymeric materials used in LEO. 1-3 The AO-induced erosion phenomena were recognized in early space shuttle missions. Many flight and ground-based experiments have been conducted to discover the reactivity of high-energy collisions of AO with various materials. 4-7 Since direct collisions with AO are restricted to the materials used on the exterior surface of spacecraft, AO reactions with the materials that are used in thermal control systems, solar panels, and other exposed facilities have been extensively studied. 8,9 The hydrocarbon polymer, polyimide, has been widely used in many space applications because of its superior physical and chemical properties, such as thermal stability, heat capacity, thermal conductivity, and heat resistance. It is well known that polyimide is eroded by hyperthermal AO bombardment in the LEO environment (see the Miller and Banks article in this issue). In fact, the erosion of Kapton H polyimide has been used as a standard to measure AO fluence, and such "Kapton equivalent fluence" is widely accepted for evaluating the erosion rate of other materials. 10 The erosion properties of polyimide need to be well understood, as the lack of knowledge of erosion behavior leads to uncertainty of the polyimide equivalent AO fluence.Another focus material in this article is fluorinated ethylene-propylene (FEP) copolymer. FEP also has been used as a thermal control material in many satellites. The erosion yield of FEP by AO is reported to be less than one tenth of that of polyimide in flight experiments; however, FEP erodes much faster in ground-based AO simulation experiments. 11 Due to the susceptibility of FEP to VUV degradation, it has been doubted that a strong synergistic effect of AO wi...

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“…[1][2][3][4][5][6][7] When spacecrafts travel at the first cosmic velocity in LEO, the surface materials collide with AOs at velocities of 7-8 km s À1 , with translational energies of 4-5 eV and fluxes of 10 13 -10 15 atoms cm À2 s À1 , which causes serious erosion and degradation to spacecraft materials. [8][9][10][11][12][13][14][15][16][17][18][19][20][21] Yellow polyimides Kapton H or Kapton NH have been widely used in LEO, for their low density, thermal stability, flexibility, and durability to vacuum ultraviolet (UV). However, they suffer from strong oxidation under hyperthermal AO attack when operating in orbit, for their elements of carbon (C), hydrogen (H), O, and nitrogen (N) are easily oxidized by the high-velocity AO interaction, to form volatile gas molecules and leave surface, resulting in mass loss of materials.…”

Section: Introductionmentioning

confidence: 99%

Hyperthermal atomic oxygen durable transparent silicon-reinforced polyimide

Qian

Xuan

2018

High Performance Polymers

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A clear poly(amic acid) was reinforced by a trisilanolphenyl polyhedral oligomeric silsesquioxane (POSS) by direct dissolution, and transparent silicon-reinforced polyimide (Si-RPI) films with different POSS loadings were obtained after curing, showing high transmittance of >90% within 380–800 nm. The Si-RPI films were exposed to a ground hyperthermal atomic oxygen (AO) beam. The erosion depths and derived erosion yields of the materials decreased with POSS loadings. At a 20 wt% POSS loading, the Si-RPI showed an erosion yield of 0.13 × 10−24 cm3 atom−1 at a fluence of 2.79 × 1020 O atoms cm−2. Surface morphology and element composition characterization on Si-RPI indicated that SiOx-based passivating layers were formed on surfaces upon the hyperthermal AO attack. This study suggests a facile way of reinforcing Si into transparent polyimide for a promising candidate of spacecraft coating material operating in low Earth orbit.

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Vacuum Ultraviolet Radiation in Sources of Hyperthermal Atomic Oxygen. Photodestruction of Polytetrafluoroethylene (PTFE) and Teflon FEP for hdication of this Radiation

Cited by 26 publications

References 13 publications

Fluorine Plasma Treatments of Poly(propylene) Films, 2 – Modeling Reaction Mechanisms and Scaling

Fluorine Plasma Treatments of Poly(propylene) Films, 2 – Modeling Reaction Mechanisms and Scaling

Mechanistic Studies of Atomic Oxygen Reactions with Polymers and Combined Effects with Vacuum Ultraviolet Light

Hyperthermal atomic oxygen durable transparent silicon-reinforced polyimide

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