Treatment surfaces with atomic oxygen excited in dielectric barrier discharge plasma of O2 admixed to N2

Shun’ko, E. V.; Belkin, V. S.

doi:10.1063/1.4732120

Cited by 5 publications

(5 citation statements)

References 16 publications

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“…To achieve a suitable labeling density for superresolution imaging, dilutions of reagents were Coverslips were plasma cleaned prior to use to remove impurities and reduce autofluorescence. Coverslips were subjected to a high frequency plasma for 1 minute in a Harrick PDC-32G plasma cleaner, handled with forceps, and were used immediately after treatment, since the effects of plasma cleaning relax exponentially with a time constant of around 4 hours [19].…”

Section: Sample Preparationsmentioning

confidence: 99%

Superresolution imaging of single DNA molecules using stochastic photoblinking of minor groove and intercalating dyes

Miller

Zhou

Wollman

et al. 2015

Methods

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AbbreviationsDIG -digoxigenin, FWHM -full width at half maximum, λ DNA -Lambda phage DNA PSF -point spread function, SNR -signal-to-noise ratio. Highlights: A bifunctional DNA construct tethers single molecules to paramagnetic beads  Intercalating (YOYO-1) and minor groove (SYTO-13) dyes are bound to DNA and photoblink  Stochastic dye photoblinking is used to obtain superresolution information via localization microscopy Abstract:As proof-of-principle for generating superresolution structural information from DNA we applied a method of localization microscopy utilizing photoblinking comparing intercalating dye YOYO-1 against minor groove binding dye SYTO-13, using a bespoke multicolor single-molecule fluorescence microscope. We used a full-length ~49 kbp λ DNA construct possessing oligo inserts at either terminus allowing conjugation of digoxigenin and biotin at opposite ends for tethering to a glass coverslip surface and paramagnetic microsphere respectively. We observed stochastic DNA-bound dye photoactivity consistent with dye photoblinking as opposed to binding/unbinding events, evidenced through both discrete simulations and continuum kinetics analysis. We analyzed dye photoblinking images of immobilized DNA molecules using superresolution reconstruction software from two existing packages, rainSTORM and QuickPALM, and compared the results against our own novel home-written software called ADEMS code. ADEMS code generated lateral localization precision values of 30-40 nm and 60-70 nm for YOYO-1 and SYTO-13 respectively at video-rate sampling, similar to rainSTORM, running more slowly than rainSTORM and QuickPALM algorithms but having a complementary capability over both in generating automated centroid distribution and cluster analyses. Our imaging system allows us to observe dynamic topological changes to single molecules of DNA in real-time, such as rapid molecular snapping events. This will facilitate visualization of fluorescentlylabeled DNA molecules conjugated to a magnetic bead in future experiments involving newly developed magneto-optical tweezers combined with superresolution microscopy.

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Section: Sample Preparationsmentioning

confidence: 99%

Superresolution imaging of single DNA molecules using stochastic photoblinking of minor groove and intercalating dyes

Miller

Zhou

Wollman

et al. 2015

Methods

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“…In consequence, there is no continuous sample heating and resolidified Si can be assumed between the pulses [8,33]. Therefore, to reduce the computational time, the time between melting intervals was Comparison of contact angles Θ of Si μ-cones on different substrates and corresponding literature surface energy values for the used substrates (silicon nitride (SiN), [36] glass, [37] aluminum (Al) [38] and tungsten (W) [39]). For the selected Si-NP layer thickness of 320 nm and laser energy density of 1.04 J cm −2 , the Si-NPs melt sequentially, and five pulses are required to completely melt the thin film (figure 3).…”

Section: Cfd Simulation With Melting Depth Profilementioning

confidence: 99%

“…(a): Cross-sectional SEM image of Si μ-cones on a Ti/W coated glass substrate with indicated contact angle Θ. (b):Comparison of contact angles Θ of Si μ-cones on different substrates and corresponding literature surface energy values for the used substrates (silicon nitride (SiN),[36] glass,[37] aluminum (Al)[38] and tungsten (W)[39]).…”

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confidence: 99%

Computational fluid dynamics simulations of silicon μ-structure formation during excimer laser modification of silicon-nanoparticle layers

2023

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The laser modification of silicon-nanoparticle layers with a nanosecond pulsed excimer laser leads to the self-organized formation of crystalline, μ-cone-shaped silicon structures with good electronic properties, which have allowed the demonstration of their potential for printed flexible electronics. With the current nanosecond laser process, silicon exhibits only short melting times, resulting in a method-defined substrate contact angle, instead of this parameter being defined by the substrate surface energy as expected for equilibrium conditions. This substrate material-independent non-equilibrium contact angle of the silicon melt was experimentally determined in this study to be Θ = 68 ± 10°. To gain deeper insight into the process of the sequential melting and the formation of the silicon μ-cone structures during laser modification, a two-dimensional computational fluid dynamics simulation was performed in COMSOL Multiphysics® solving the Navier-Stokes equation for incompressible fluids. The simulation uses an effective medium approach by applying the conservative level set method to describe the porous silicon-nanoparticle layer. Its sequential melting during the pulsed laser modification is modeled using a newly developed simulation methodology, which uses a time- and depth-dependent dynamic viscosity of the molten silicon. The simulation was carried out for different laser energy densities and verified using scanning electron microscopy images of corresponding laser-modified samples. The simulation results agree well with the experiment and were subsequently used to optimize the laser process.

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“…When equilibrium exists between ionization and recombination, the plasma will burn in a stable manner [28]. Minimum ionization energy of an electron is required to ionize an atom and if energy transfer due to the impact is less than the ionization energy, then the struck atom is excited [29].…”

Section: Application Of Plasmamentioning

confidence: 99%

Treatment of Metal and Textile Fabrics Surfaces Using Plasma

Mansour

Elshafei

2020

AJARR

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In the next few years, the progresses in plasma technology will play an increasing role in our lives, providing new sources of energy. The studies conducted by scientists on plasma state not only accelerate technological developments, but also describe the characteristics and types of plasmas and improve the understanding of natural phenomena. Plasmas represent the recent fourth state of matter in addition to the three fundamental states namely solids, liquids and gases. Plasma is defined as a state of matter where the gas phase is energized until atomic electrons are no longer associated with any particular atomic nucleus or as a matter that exists as a mixture of neutral atoms, ions, electrons, molecular ions and molecules present in excited and ground states. Plasma is the result of the ionization of atoms and the level of ionization is mainly controlled by temperature, where an increase of temperature increases the degree of ionization. The term “plasma” introduced by the scientist Irving Langmuir (1928) and comes from a Greek word that means moldable or Jelly material. Plasma may be produced by either heating a gas at high temperature until it is ionized or by subjecting it to a strong electric or magnetic fields. Investigators categorized plasma as non-thermal and thermal plasma. In non-thermal plasma, the electrons are at a much higher temperature than the ions and neutral particles however, in thermal plasma, the electrons and heavier particles are in thermal equilibrium at the same temperature. Plasma treatment of surfaces is initiated when electrons, molecules or neutral gas atoms, positive ions, ions along with excited gas molecules and atoms come together and interact with a particular surface. Plasma treatments can be utilized to develop thin protective layers to metal surfaces, as surface pretreatment and cleaning are the most important operations of coating technologies, in addition to induce both surface modifications and bulk property enhancements of textile materials.

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Treatment surfaces with atomic oxygen excited in dielectric barrier discharge plasma of O2 admixed to N2

Cited by 5 publications

References 16 publications

Superresolution imaging of single DNA molecules using stochastic photoblinking of minor groove and intercalating dyes

Superresolution imaging of single DNA molecules using stochastic photoblinking of minor groove and intercalating dyes

Computational fluid dynamics simulations of silicon μ-structure formation during excimer laser modification of silicon-nanoparticle layers

Treatment of Metal and Textile Fabrics Surfaces Using Plasma

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