On the heating of nano- and microparticles in process plasmas

Maurer, H. R.; Kersten, Holger

doi:10.1088/0022-3727/44/17/174029

Cited by 64 publications

(49 citation statements)

References 57 publications

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Section: Plasma Synthesis Of Nanomaterials and Nanostructured Materialsmentioning

confidence: 99%

“…There are significant gaps in knowledge in understanding the interaction between plasmas and nanomat erials. Nanomaterials experience strong fluxes of radicals and charged particles with strong energy exchange with the plasma environment, leading to extreme non-equilibrium conditions during growth, as shown schematically in figure 13 [74]. Furthermore, the effects of the nanomaterials immersed in or in intimate contact with the plasma on the plasma itself need to be better understood.…”

Section: Plasma Synthesis Of Nanomaterials and Nanostructured Materialsmentioning

confidence: 99%

See 1 more Smart Citation

The 2017 Plasma Roadmap: Low temperature plasma science and technology

Adamovich

Baalrud

Bogaerts

et al. 2017

J. Phys. D: Appl. Phys.

780

549

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Section: Plasma Synthesis Of Nanomaterials and Nanostructured Materialsmentioning

confidence: 99%

Section: Plasma Synthesis Of Nanomaterials and Nanostructured Materialsmentioning

confidence: 99%

The 2017 Plasma Roadmap: Low temperature plasma science and technology

Adamovich

Baalrud

Bogaerts

et al. 2017

J. Phys. D: Appl. Phys.

780

549

View full text Add to dashboard Cite

“…Изучение поверхностных слоев различных материа-лов и их модификации в связи с развитием нанотех-нологий является актуальной темой исследований [1][2][3]. В [4][5][6] были опубликованы первые данные о воздей-ствии пылевой плазмы на полимерные частицы.…”

unclassified

“…В разрядной трубке зажигался стратифицированный тлеющий разряд при условиях: Ne, p = 40 Pa, i = 2.5 mA. Монодисперсные сферические частицы меламин-формальдегида (MF-R), которые вбрасывались в плазму разряда, имели диаметр 7.3 ± 0.4 µm, плотность 1.5 g/sm 3 . В подобранных усло-виях частицы зависали в плазменно-пылевых ловушках и находились под воздействием плазмы от 5 до 25 min.…”

unclassified

Изменение Текстуры Поверхности Полимерных Материалов В Пылевой Плазме

Карасев¹,

Дзлиева²,

Горбенко³

et al. 2017

Журнал Технической Физики

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Исследовано изменение текстуры поверхности полимерных частиц в пылевой плазме. Монодисперсные сферические частицы меламин-формальдегида вбрасывались в плазму тлеющего разряда в неоне. При определенном токе разряда и давлении газа в разрядной трубке частицы зависали в плазменно-пылевых ловушках и находились под воздействием плазмы в течение времени от 5 до 25 min. Далее частицы извлекались, а собранный материал изучался с помощью растрового сканирующего электронного микро-скопа. Среди полученных результатов установлено изменение диаметра и шероховатости поверхности от времени пребывания частиц в пылевой плазме. Обнаружено, что усредненные на длине оценки абсолютные отклонения всех точек профиля поверхности находились в наноразмерном диапазоне. Установлено время полной деградации частиц в условиях эксперимента.

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“…The emissivity is a size dependent property when the wavelength of the emitted radiation is larger than the size of the particle, resulting in that smaller nanoparticles have a lower emissivity [58].…”

Section: Surface Growth and Coolingmentioning

confidence: 99%

Controlling the growth of nanoparticles produced in a highpower pulsed plasma

Gunnarsson¹

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Nanotechnology can profoundly benefit our health, environment and everyday life. In order to make this a reality, both technological and theoretical advancements of the nanomaterial synthesis methods are needed. A nanoparticle is one of the fundamental building blocks in nanotechnology and this thesis describes the control of the nucleation, growth and oxidation of titanium particles produced in a pulsed plasma. It will be shown that by controlling the process conditions both the composition (oxidation state) and size of the particles can be varied. The experimental results are supported by theoretical modeling.If processing conditions are chosen which give a high temperature in the nanoparticle growth environment, oxygen was found to be necessary in order to nucleate the nanoparticles. The two reasons for this are 1: the lower vapor pressure of a titanium oxide cluster compared to a titanium cluster, meaning a lower probability of evaporation, and 2: the ability of a cluster to cool down by ejecting an oxygen atom when an oxygen molecule condenses on its surface. When the oxygen gas flow was slightly increased, the nanoparticle yield and oxidation state increased. A further increase caused a decrease in particle yield which is attributed to a slight oxidation of the cathode. By varying the oxygen flow, it was possible to control the oxidation state of the nanoparticles without fully oxidizing the cathode. Pure titanium nanoparticles could not be produced in a high vacuum system because oxygen containing gases such as residual water vapour have a profound influence on nanoparticle yield and composition. In an ultrahigh vacuum system titanium nanoparticles without significant oxygen contamination were produced by reducing the temperature of the growth environment and increasing the pressure of an argon-helium gas mixture within which the nanoparticles grew. The dimer formation rate necessary for this is only achievable at higher pressures. After a dimer has formed, it needs to grow by colliding with a titanium atom followed by cooling by collisions with multiple buffer gas atoms. The condensation event heats up the cluster to a temperature much higher than the gas temperature, where it is during a short time susceptible to evaporation. When the clusters' internal energy has decreased by collisions with the gas to less than the energy required to evaporate a titanium atom, it is temporarily stable until the next condensation event occurs. The temperature difference by which the cluster has to cool down before it is temporarily stable is exactly as many kelvins as the gas temperature. The addition of helium was found to decrease the temperature of the gas, making it possible for nanoparticles of pure titanium to grow. The process window where this is possible was determined and the results presented opens up new iv possibilities to synthesize particles with a controlled contamination level and deposition rate.The size of the nanoparticles has been controlled by three means. The first is to change the electr...

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On the heating of nano- and microparticles in process plasmas

Cited by 64 publications

References 57 publications

The 2017 Plasma Roadmap: Low temperature plasma science and technology

The 2017 Plasma Roadmap: Low temperature plasma science and technology

Изменение Текстуры Поверхности Полимерных Материалов В Пылевой Плазме

Controlling the growth of nanoparticles produced in a highpower pulsed plasma

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