Extended metastable Al solubility in cubic VAlN by metal-ion bombardment during pulsed magnetron sputtering: film stress <i>vs</i> subplantation

Greczyński, Grzegorz; Mráz, Stanislav; Rueß, Holger; Hans, Marcus; Lu, Jun; Hultman, Lars; Schneider, Jochen M.

doi:10.1063/1.4991640

Cited by 19 publications

(11 citation statements)

References 59 publications

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“…The approach described above has been used to grow N-doped bcc-CrN0.05 nanostructured films combining metallic and ceramic properties; 18 hard, stress-free Ti0.39Al0.61N; 19 single-phase NaCl-structure Ti1-xSixN with extremely-high SiN concentrations; 20 unprecedented AlN supersaturation in single-phase cubic V1-xAlxN; 21,22 and hard, dense Ti0.92Ta0.08N and Ti0.41Al0.51Ta0.08N alloys grown with no external heating. 23,24 In each of these examples, the crucial step was synchronization of the substrate bias pulse to the metal-ion portion of the HiPIMS pulse, which requires detailed knowledge, typically provided by the time-resolved mass spectrometry, of the time evolution of metal-and gas-ion fluxes incident at the substrate.…”

Section: Introductionmentioning

confidence: 99%

Time evolution of ion fluxes incident at the substrate plane during reactive high-power impulse magnetron sputtering of groups IVb and VIb transition metals in Ar/N2

Greczyński

Zhirkov

Petrov

et al. 2018

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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Reactive transition-metal (TM) nitride film growth employing bias-synchronized high power impulse magnetron sputtering (HiPIMS) requires a detailed knowledge of the time evolution of metal-and gas-ion fluxes incident at the substrate plane in order to precisely tune momentum transfer and, hence, provide the recoil density and energy necessary to eliminate film porosity at low deposition temperatures without introducing significant film stress. Here, we use energy-and time-dependent mass spectrometry to analyze the evolution of metal-and gas-ion fluxes at the substrate plane during reactive HiPIMS sputtering of Groups IVb and VIb TM targets in Ar/N2 atmospheres. The time-and energy-integrated metal/gas ion ratio + / + incident at the substrate is significantly lower for Group IVb TMs (ranging from 0.2 for Ti to 0.9 for Hf), due to high N2 reactivity which results in severely reduced target sputtering rates and, hence, decreased rarefaction. In contrast, for less reactive Group VIb metals, sputtering rates are similar to those in pure Ar as a result of significant gas heating and high + / + ratios, ranging from 2.3 for Cr to 98.1 for W. In both sets of experiments, the peak target current density is maintained constant at 1 A/cm 2. Within each TM group, + / + scales with increasing metal-ion mass. For the Group-VIb elements, sputtered-atom Sigmund-Thompson energy distributions are preserved long after the HiPIMS pulse, in contradistinction to Group-IVb TMs for which the energy distributions collapse into narrow thermalized peaks. For all TMs, the N + flux dominates that of N2 + ions, as the

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Section: Introductionmentioning

confidence: 99%

Time evolution of ion fluxes incident at the substrate plane during reactive high-power impulse magnetron sputtering of groups IVb and VIb transition metals in Ar/N2

Greczyński

Zhirkov

Petrov

et al. 2018

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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“…This effectively suppresses the formation of the thermodynamically stable w-AlN phase as the activation energy for bulk diffusion is larger than for surface diffusion. The volume fraction χ of the second-phase w-AlN precipitates, estimated from NaCl phase 002 and wurtzite 1010 peak intensities integrated over all sample title angles and normalized to random powder diffraction values, is plotted in Figure 5 as a function of Al concentration x for three series of V 1−x Al x N films grown with (a) conventional DCMS and dc bias of −100 V, (data points from [20]) (b) hybrid Al-HiPIMS/V-DCMS co-sputtering with -60 V bias pulses synchronized to the metal-ion rich portions of the HiPIMS pulses, and (c) hybrid Al-HiPIMS/V-DCMS co-sputtering with V s = −300 V. Linear extrapolations of χ(x) data plots towards the χ = 0 horizontal line are used to estimate the critical Al concentration value x max , above which w-AlN phase is detected, corresponding to metastable solubility limit of Al in the NaCl crystal lattice. Clearly, solubility is lowest for the V 1−x Al x N films grown with conventional DCMS technique and with a DC substrate bias of -100 V, x max = 0.52.…”

Section: Resultsmentioning

confidence: 99%

“…For example, for the TiAlN material system, x max~0 .40 at the growth temperature T s = 500 • C [14,15]. In the case of ZrAlN, values between 0.13 and 0.43 are reported [16][17][18], while x max is in the range 0.52-0.54 for VAlN [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

“…The powering of the DCMS source is chosen such that the film surface, where high adatom mobility and gas-ion-induced mixing drives the system towards thermodynamic equilibrium, is dominated by V atoms, which arrive predominantly between HiPIMS pulses and form NaCl-structure VAlN crystallites with low Al content. To avoid precipitation of the thermodynamically favored w-AlN phase, high-energy Al + ions deposited exclusively during thẽ 100-µs-long metal-ion rich HiPIMS phase are directly subplanted into cubic low-x V 1−x Al x N grains buried below the high-mobility surface zone, where the activation energy for diffusion is larger than at the very surface, which enables formation of single-phase VAlN solid solution with record-high x max of 0.75 [20,22,28].…”

Section: Introductionmentioning

confidence: 99%

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Control over the Phase Formation in Metastable Transition Metal Nitride Thin Films by Tuning the Al+ Subplantation Depth

et al. 2018

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The performance of transition metal nitride based coatings deposited by magnetron sputtering, in a broad range of applications including wear-protective coatings on cutting tools and components in automotive engines, is determined by their phase content. The classical example is the precipitation of thermodynamically-favored wurtzite-AlN while alloying TiN with Al to obtain ternary single phase NaCl-structure films with improved high-temperature oxidation resistance. Here, we report on reactive high-power impulse and direct current magnetron co-sputtering (HiPIMS/DCMS) growth of Ti0.31Al0.69N and Zr0.48Al0.52N thin films. The Al concentrations are intentionally chosen to be higher than theoretically predicted solubility limits for the rock salt structure. The goal is to investigate the effect of the incident Al+ energy EAl+, controlled by varying the amplitude of the substrate bias applied synchronously with the Al+-rich portion of the ion flux from the Al-HiPIMS source, on the crystalline phase formation. For EAl+ ≤ 60 eV, films contain predominantly the wurtzite phase. With increasing EAl+, and thus, the Al subplantation depth, the relative fraction of the NaCl structure increases and eventually for EAl+ > 250 eV, Ti0.31Al0.69N and Zr0.48Al0.52N layers contain more than 95% of the rock salt phase. Thus, the separation of the film forming species in time and energy domains determines the phase formation of Ti0.31Al0.69N and Zr0.48Al0.52N layers and enables the growth of the cubic phase outside of the predicted Al concentration range. The new film growth concept can be applied to the entire family of multinary transition metal aluminum nitrides, where one of the metallic film constituents is available in the ionized form while the other arrives as neutral.

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“…Recently, it has been demonstrated for Cr 0.8 Al 0.2 N that a compressive stress state of −4 GPa results in an elastic modulus increase of 150 GPa, when compared to the stress-free material [4]. In addition, compressive residual stresses are utilized to stabilize the metastable cubic phase of MAlN (M = Ti, V, Cr) [5,6].…”

Section: Introductionmentioning

confidence: 99%

Stress-Dependent Elasticity of TiAlN Coatings

et al. 2019

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We investigate the effect of continuous vs. periodically interrupted plasma exposure during cathodic arc evaporation on the elastic modulus as well as the residual stress state of metastable cubic TiAlN coatings. Nanoindentation reveals that the elastic modulus of TiAlN grown at floating potential with continuous plasma exposure is 7%–11% larger than for coatings grown with periodically interrupted plasma exposure due to substrate rotation. In combination with X-ray stress analysis, it is evident that the elastic modulus is governed by the residual stress state. The experimental dependence of the elastic modulus on the stress state is in excellent agreement with ab initio predictions. The macroparticle surface coverage exhibits a strong angular dependence as both density and size of incorporated macroparticles are significantly lower during continuous plasma exposure. Scanning transmission electron microscopy in combination with energy dispersive X-ray spectroscopy reveals the formation of underdense boundary regions between the matrix and TiN-rich macroparticles. The estimated porosity is on the order of 1% and a porosity-induced elastic modulus reduction of 5%–9% may be expected based on effective medium theory. It appears reasonable to assume that these underdense boundary regions enable stress relaxation causing the experimentally determined reduction in elastic modulus as the population of macroparticles is increased.

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Extended metastable Al solubility in cubic VAlN by metal-ion bombardment during pulsed magnetron sputtering: film stress vs subplantation

Cited by 19 publications

References 59 publications

Time evolution of ion fluxes incident at the substrate plane during reactive high-power impulse magnetron sputtering of groups IVb and VIb transition metals in Ar/N2

Time evolution of ion fluxes incident at the substrate plane during reactive high-power impulse magnetron sputtering of groups IVb and VIb transition metals in Ar/N2

Control over the Phase Formation in Metastable Transition Metal Nitride Thin Films by Tuning the Al+ Subplantation Depth

Stress-Dependent Elasticity of TiAlN Coatings

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