Impact of Metals on (Star)Dust Chemistry: A Laboratory Astrophysics Approach

Berard, R.; Demyk, K.; Simon, Aude; Nuñez-Reyes, Dianailys; Mastrorocco, Fabrizio; Sabbah, Hassan; Joblin, C.

doi:10.3389/fspas.2021.654879

Cited by 5 publications

(7 citation statements)

References 82 publications

(101 reference statements)

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“…The plateau in the AgI line intensity suggests an additional source of release of Ag atoms into the plasma compared to the silver sputtering from the target since the electron temperature is decreasing at that time (Figure 3). This additional source could be either the AgNPs or the dissociation of Ag n clusters and complexes of Ag with hydrocarbons whose presence has been demonstrated in our earlier study (Bérard et al, 2021). The coinciding plateau in the intensity of the AgI line and the bump in the intensity of the ArI line can be associated with the moment when the AgNPs attach to the organosilicon NPs to form the core-satellite assemblies (raspberry-like NPs).…”

Section: Transition In the Plasma Behavior During Simultaneous Plasma...mentioning

confidence: 65%

“…Although these studies are relatively recent and the achievements are not yet numerous, dust formation in reactive plasmas based on large chemical precursors has already been identified as promising for the development of thin nanocomposite films for microelectronic devices, sensor applications, healthcare applications, among others. In addition, it has recently been shown that the formation of dust nanoparticles in HMDSO-based plasmas appears to be of some interest for the study of stardust formation in laboratory experiments (Bérard et al, 2019;Bérard et al, 2021), as HMDSO contains key elements involved in stardust: carbon, oxygen, and silicon (Henning, 2010).…”

Section: Introductionmentioning

confidence: 99%

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Layer-by-layer structured nanocomposite deposits from plasma-synthesized organosilicon nanoparticles and organosilicon nanoparticles decorated with Ag nanoparticles by taking advantage of cyclic nanoparticle formation in Ar/HMDSO reactive plasmas

Bérard,

Garofano,

Joblin

et al. 2024

Front. Nanotechnol.

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Rational engineering of thin nanocomposite layers, deposited in reactive plasmas, requires knowledge on the plasma behavior in order to produce multifunctional deposits with tailored properties (structural, optical, electrical, etc.) This work presents an experimental study of nanoparticles synthesized in the plasma gas-phase and their subsequent use as building-blocks to form layer-by-layer nanostructures. The experiment is performed in a plasma process that successfully combines plasma polymerization of an organosilicon molecular precursor (hexamethyldisiloxane, HMDSO) and sputtering of a metallic (silver) target. Pulsed injection of the precursor is found to promote cyclic nanoparticle formation in Ar/HMDSO reactive plasmas. The plasma electron temperature is found to vary in the range 1.6—2.2 eV as derived from time-resolved optical emission spectroscopy of the plasma energetic conditions. This diagnostic method is also shown to provide a reliable tool for online monitoring of the nanoparticle synthesis process. Two types of layer-by-layer structured nanocomposites can be obtained depending on the type of nanoparticles synthesized: (i) organosilicon nanoparticles of size less than 100 nm in all studied plasma conditions for a large quantity of injected HMDSO and (ii) raspberry-like nanoparticles of size less than 150 nm when the quantity of injected HMDSO is reduced. The organosilicon nanoparticle growth follows a polydimethylsiloxane (PDMS)-like oligomerization scheme in which the R2-Si(-O)2 silicon bond tends towards the formation of polymeric structure in a R3-Si(-O)1 silicon chemical environment, containing Si-(CH2)-Si type bridges that are involved in cross-linking. The elemental composition of the raspberry-like nanoparticles is similar to that of the organosilicon nanoparticles, supplemented by the Ag component. The decorating silver nanoparticles are ∼15 nm of size, round in shape and polycrystalline. There is no evidence for silver oxides in the nanostructures. The Si-O-Ag bridges, revealed by infrared spectroscopy, suggest the presence of junction sites between the metallic and the organosilicon parts of the raspberry-like nanoparticles. The silver nanoparticles are found to decorate the organosilicon nanoparticles to form the raspberry-like nanoparticles in the plasma gas-phase, before being deposited. This reveals a very interesting phenomenon of simultaneous growth of the silver- and organosilicon-parts in the plasma without mixing during the nucleation phase.

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Section: Transition In the Plasma Behavior During Simultaneous Plasma...mentioning

confidence: 65%

Section: Introductionmentioning

confidence: 99%

Layer-by-layer structured nanocomposite deposits from plasma-synthesized organosilicon nanoparticles and organosilicon nanoparticles decorated with Ag nanoparticles by taking advantage of cyclic nanoparticle formation in Ar/HMDSO reactive plasmas

Bérard,

Garofano,

Joblin

et al. 2024

Front. Nanotechnol.

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“…Currently, the investigation of the emergence and growth of dust particles in a 13,56 MHz radio-frequency (RF) discharge plasma, sustained in a mixture of argon and hexamthyldisiloxane (Ar-HMDSO) with HMDSO being the molecular precursor, is being carried out [24 -26]. Based on the formation of particles in a dusty plasma, the mechanisms of cosmic dust formation and the synthesis of its analogues in laboratory conditions are being investigated [27].…”

Section: Introductionmentioning

confidence: 99%

THE Formation of chondrule-like particles in RF discharge plasma

Abdirakhmanov

2023

phst

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Chondrules are fundamental components of chondritic meteorites and play a vital role in understanding the formation of the early solar system. This study focuses on the synthesis of chondrule-like particles in a plasma environment using a radiofrequency (RF) discharge. The experimental setup involves a vacuum chamber where argon gas, hexamethyldisiloxane (HMDSO), and ferrocene vapors are introduced. The plasma burning duration is optimized to facilitate chondrule formation, followed by analysis of the synthesized particles using scanning electron microscopy (SEM) and energy dispersive analysis. The results demonstrate the successful synthesis of chondrule-like particles with diverse sizes and morphologies. SEM imaging reveals particles ranging from 80 to 378 nm in diameter, exhibiting rounded and non-uniform shapes. Energy dispersive analysis confirms the presence of iron, carbon, oxygen, and silicon in the synthesized particles. Iron and carbon originate from the ferrocene and HMDSO precursors, respectively, while oxygen may indicate oxidation or the presence of oxide groups. Silicon, the main component, contributes to the key characteristics of the chondrule-like structures. These findings contribute to the understanding of chondrule formation mechanisms and pave the way for further investigations using combined discharges to simulate shock waves or nebular lightning. Additionally, the study suggests the possibility of introducing additional chondrule building blocks, such as magnesium and phosphorus, to explore their effects on particle synthesis and composition.

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“…Molecular mass spectrometry analysis revealed that various carbonaceous samples contain a dominant peak at m / z = 202.078 corresponding to a polycyclic aromatic hydrocarbon (PAH) of formula C 16 H 10 . These samples include soot particles generated in flames, diesel fuels and particulate matter, cosmic dust analogues, , and carbonaceous chondrite meteorites. − Shukla and Koshi showed that in combustion reactions, different chemical pathways lead to the preferential formation of pyrene or fluoranthene. Each isomer could then lead to different species by subsequent growth.…”

Section: Introductionmentioning

confidence: 99%

“…The technique has been applied to soot samples. , Recent work in our group has demonstrated the very high sensitivity (attomole level) of the two-step LDI-MS in following molecular families of PAHs, carbon clusters, hydrogenated carbon clusters, and fullerenes. We have applied this technique to the analysis of laboratory analogues of stardust ,, and of meteorite samples. ,,, An originality of our setup is to be equipped with an ion trap so that ions can be activated by collisions or by absorption of photons and their dissociation features used to obtain information on the structure of the ions.…”

Section: Introductionmentioning

confidence: 99%

Isomer Differentiation of Trapped C₁₆H₁₀⁺ Using Low-Energy Collisions and Visible/VUV Photons

et al. 2022

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Polycyclic aromatic hydrocarbons are major species in astrophysical environments, and this motivates their study in samples of astrochemical interest such as meteorites and laboratory analogues of stardust. Molecular analyses of carbonaceous matter in these samples show a dominant peak at m/z = 202.078 corresponding to C 16 H 10 . Obtaining information on the associated isomeric structures is a challenge for the molecular analysis of samples available in very small quantities (mg or less). Here we show that coupling laser desorption ionization mass spectrometry with ion trapping opens up the possibility of unraveling isomers by activating ion fragmentation via collisions or photon absorption. We report the best criteria for differentiating isomers with comparable dissociation energies, namely pyrene, fluoranthene, and 9-ethynylphenanthrene, on the basis of the parent dissociation curve and the ratio of dehydrogenation channels. Photoabsorption schemes (multiple photon absorption in the visible range and single photon absorption at 10.5 eV) are more effective in differentiating these isomers than activation by low energy collisions. The impact of the activation scheme on the fragmentation kinetics and dehydrogenation pathways is discussed. By analyzing the 10.5 eV photodissociation measurements with a simple kinetic model, we were able to derive a branching ratio for the H and 2H/H 2 loss channels of the parent ions. The results suggest a role in the formation of H 2 for bay hydrogens that are present in both fluoranthene and 9-ethynylphenanthrene. In addition, we suggest for the latter the presence of a highly competitive 2H loss channel, possibly associated with the formation of a pentagonal ring.

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Impact of Metals on (Star)Dust Chemistry: A Laboratory Astrophysics Approach

Cited by 5 publications

References 82 publications

Layer-by-layer structured nanocomposite deposits from plasma-synthesized organosilicon nanoparticles and organosilicon nanoparticles decorated with Ag nanoparticles by taking advantage of cyclic nanoparticle formation in Ar/HMDSO reactive plasmas

Layer-by-layer structured nanocomposite deposits from plasma-synthesized organosilicon nanoparticles and organosilicon nanoparticles decorated with Ag nanoparticles by taking advantage of cyclic nanoparticle formation in Ar/HMDSO reactive plasmas

THE Formation of chondrule-like particles in RF discharge plasma

Isomer Differentiation of Trapped C₁₆H₁₀⁺ Using Low-Energy Collisions and Visible/VUV Photons

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Impact of Metals on (Star)Dust Chemistry: A Laboratory Astrophysics Approach

Cited by 5 publications

References 82 publications

Layer-by-layer structured nanocomposite deposits from plasma-synthesized organosilicon nanoparticles and organosilicon nanoparticles decorated with Ag nanoparticles by taking advantage of cyclic nanoparticle formation in Ar/HMDSO reactive plasmas

Layer-by-layer structured nanocomposite deposits from plasma-synthesized organosilicon nanoparticles and organosilicon nanoparticles decorated with Ag nanoparticles by taking advantage of cyclic nanoparticle formation in Ar/HMDSO reactive plasmas

THE Formation of chondrule-like particles in RF discharge plasma

Isomer Differentiation of Trapped C16H10+ Using Low-Energy Collisions and Visible/VUV Photons

Contact Info

Product

Resources

About

Isomer Differentiation of Trapped C₁₆H₁₀⁺ Using Low-Energy Collisions and Visible/VUV Photons