Nfw Nick Thissen scite author profile

Molybdenum oxide (MoOx) films have been deposited by atomic layer deposition using bis(tert-butylimido)-bis(dimethylamido)molybdenum and oxygen plasma, within a temperature range of 50–350 °C. Amorphous film growth was observed between 50 and 200 °C at a growth per cycle (GPC) around 0.80 Å. For deposition temperatures of 250 °C and higher, a transition to polycrystalline growth was observed, accompanied by an increase in GPC up to 1.88 Å. For all deposition temperatures the O/Mo ratio was found to be just below three, indicating the films were slightly substoichiometric with respect to MoO3 and contained oxygen vacancies. The high purity of the films was demonstrated in the absence of detectable C and N contamination in Rutherford backscattering measurements, and a H content varying between 3 and 11 at. % measured with elastic recoil detection. In addition to the chemical composition, the optical properties are reported as well.

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Direct-Write Atomic Layer Deposition of High-Quality Pt Nanostructures: Selective Growth Conditions and Seed Layer Requirements

Mackus

Thissen

Mulders³

et al. 2013

J. Phys. Chem. C

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Electron beam-induced deposition (EBID) enables the direct-write patterning of metallic structures with sub-10 nm lateral resolution without the use of resist films or etching/lift-off steps but generally leads to material of poor quality and suffers from a low throughput. These shortcomings were mitigated in recent work by combining EBID with atomic layer deposition (ALD). This direct-write ALD technique comprises the patterning of a thin seed layer by EBID followed by selective thickening of the pattern by ALD. In this work, the throughput of direct-write ALD was drastically improved based on new insights into how the ALD growth initiates on EBID material, and in addition, the conditions for selective ALD growth were identified. The required electron dose was reduced by 2 orders of magnitude to ∼11 pC/μm 2 by exposing the EBID seed layers to O 2 in the ALD reactor just before the ALD building step. This improvement of the technique allows for nanopatterning with a throughput comparable to electron beam lithography (EBL).

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Low‐temperature atomic layer deposition of MoO_x for silicon heterojunction solar cells

Macco

Vos

Thissen

et al. 2015

Physica Rapid Research Ltrs

102

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ContentsFull text on our homepage at www.pss-rapid.com FRONT COVERDespite its simple formula, AgO is a complex transition metal oxide, which contains both mono-and trivalent silver cations, i.e. Ag(I)Ag(III)O 2 . Ag(I) (represented by silver balls in the cover image) and Ag(III) (blue balls in the image) form separate layers in the crystal structure of this compound. Disproportionation (i.e. charge density wave) opens up a band gap at the Fermi level and AgO is a narrow band gap semiconductor (ca. 1.0-1.1 eV). The question arises whether this mixed-valence system might be turned into metal at large external pressures. As shown by , theoretical density functional theory calculations with use of an expensive hybrid functional reproduce very well the band gap of AgO. The calculations also indicate that AgO could be turned into a metal at pressures exceeding 45 GPa. Metallization is concomitant with the phase transition to the more stable polymorphic form, which is nevertheless disproportionated, just like its predecessor. The new metallic polymorph preserves a pseudo-gap and it shows rather small density of states at the Fermi level. Comproportionation, i.e. reversal of the charge density wave and the concomitant formation of genuine Ag(II) oxide, must require pressures larger than 70 GPa, which was the highest pressure studied here. Chemistry of silver(II) again proves to be very different from that of copper(II), as seen from the AgO-CuO comparison. BACK COVERPerforated systems constitute one of the rising and most promising fields in the study of mechanical metamaterials capable of exhibiting auxetic behavior. This is mainly due to the fact that these systems have the potential to exhibit a large range of Poisson's ratios whilst being relatively easy to produce. In this work (Mizzi et al.,, novel slit perforation patterns which can be used to produce systems capable of exhibiting giant negative Poisson's ratios have been proposed for the first time. These systems, which are produced either through straight line or 'I'-shaped slits, mimic the deformation mechanisms of a variety of auxetic systems, such as rotating rectangles and parallelograms, re-entrant honeycombs and anti-tetrachiral systems (see back cover). Besides exhibiting giant negative Poisson's ratios, these systems also have the added advantages of being easy to manufacture, and involve minimal material waste, since the perforations are introduced as cuts or slits rather than, for example, area perforations.This work has been funded through the Malta Council for Science and Technology through the R&I-2012-061 (SMESH) Project. The authors would also like to thank Jean Claude Vancell for designing the back cover. Towards a metallic quasi-d 9 system without copper: AgO at high pressure AgO is a prototypical mixed-valence compound, and a narrow-bandgap semiconductor. The authors show, using hybrid DFT calculations, that AgO should undergo the imaginary phonon-driven structural phase transition at a pressure of ca. 45 GPa with a concomitant metallization. T...

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The effect of residual gas scattering on Ga ion beam patterning of graphene

Thissen

Vervuurt

Mulders³

et al. 2015

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The patterning of graphene by a 30 kV Ga+ focused ion beam (FIB) is studied by in-situ and ex-situ Raman spectroscopy. It is found that the graphene surrounding the patterned target area can be damaged at remarkably large distances of more than 10 μm. We show that scattering of the Ga ions in the residual gas of the vacuum system is the main cause of the large range of lateral damage, as the size and shape of the tail of the ion beam were strongly dependent on the system background pressure. The range of the damage was therefore greatly reduced by working at low pressures and limiting the total amount of ions used. This makes FIB patterning a feasible alternative to electron beam lithography as long as residual gas scattering is taken into account.

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Synthesis of single-walled carbon nanotubes from atomic-layer-deposited Co3O4 and Co3O4/Fe2O3 catalyst films

Thissen

Verheijen

Houben

et al. 2017

Carbon

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Nfw Nick Thissen

Atomic layer deposition of molybdenum oxide from (NtBu)2(NMe2)2Mo and O2 plasma

Direct-Write Atomic Layer Deposition of High-Quality Pt Nanostructures: Selective Growth Conditions and Seed Layer Requirements

Low‐temperature atomic layer deposition of MoO_x for silicon heterojunction solar cells

The effect of residual gas scattering on Ga ion beam patterning of graphene

Synthesis of single-walled carbon nanotubes from atomic-layer-deposited Co3O4 and Co3O4/Fe2O3 catalyst films

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Nfw Nick Thissen

Atomic layer deposition of molybdenum oxide from (NtBu)2(NMe2)2Mo and O2 plasma

Direct-Write Atomic Layer Deposition of High-Quality Pt Nanostructures: Selective Growth Conditions and Seed Layer Requirements

Low‐temperature atomic layer deposition of MoOx for silicon heterojunction solar cells

The effect of residual gas scattering on Ga ion beam patterning of graphene

Synthesis of single-walled carbon nanotubes from atomic-layer-deposited Co3O4 and Co3O4/Fe2O3 catalyst films

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Product

Resources

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Low‐temperature atomic layer deposition of MoO_x for silicon heterojunction solar cells