Role of Tin+ and Aln+ ion irradiation (n=1, 2) during Ti1-xAlxN alloy film growth in a hybrid HIPIMS/magnetron mode

Greczyński, Grzegorz; Lu, Jun; Johansson, Mats; Jensen, Jens; Petrov, I.; Greene, J. E.; Hultman, Lars

doi:10.1016/j.surfcoat.2012.04.024

Cited by 126 publications

(65 citation statements)

References 35 publications

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“…A range of dc bias voltages between -20 V and -80 V was applied to the substrate and the deposition time was 100 s, yielding 300 nm thick films, corresponding to a growth rate of about 8 unit cells/s in the c-axis direction. The typical floating potential for a DCMS process is around -10 V in this deposition system [23]. The power of the heater was 0 W, 5 000 W or 10 000 W, corresponding to approximately room temperature (RT), 400 °C, and 550 °C respectively, as calibrated by thermocouple.…”

Section: Methodsmentioning

confidence: 99%

Direct current magnetron sputtered ZrB2 thin films on 4H-SiC(0001) and Si(100)

et al. 2014

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Section: Methodsmentioning

confidence: 99%

Direct current magnetron sputtered ZrB2 thin films on 4H-SiC(0001) and Si(100)

et al. 2014

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“…This provides increased capability for controlling film microstructure, and hence physical properties, while minimizing ionbombardment-induced compressive stress (such as obtained from rare-gas ion irradiation) during HIPIMS film growth utilizing a substrate bias synchronized to the metal-ion dominated portion of the pulses. 2,3,5 Metal, as opposed to the noble-gas, ions primarily end on lattice sites. 5 HIPIMS discharges are complex, time-dependent, and operate far from equilibrium.…”

Section: Discussionmentioning

confidence: 99%

“…This has been shown, for example, to be essential for controlling phase composition, while minimizing compressive residual stresses, in pseudobinary TM nitride thin films. 2,3,8 The approach is based on controllably adjusting plasma electron-energy distributions g(Ee) by the proper choice of sputtering-gas mixtures, since the ionization probability of sputtered metal atoms during HIPIMS is determined by the g(Ee) high- of the sputtering gas (Ne, Ar, Kr, or Xe). The average target power P and total gas pressure P were maintained constant at 1 kW and 0.4 Pa (3 mTorr).…”

Section: Discussionmentioning

confidence: 99%

“…Low-energy metal-ion irradiation of growing films during high-power pulsed magnetron sputter deposition (HIPIMS), 1 with the substrate bias synchronized to the metal-ion-rich portion of the pulses, 2,3 has recently been shown to provide microstructure densification and surface smoothening, without introducing the large increases in film compressive stress reported for noblegas ion irradiation during dc magnetron sputter deposition, 4,5 provided that the metal-ion flux incident at the substrate is primarily singly-ionized. In contrast, multiply-charged metal-ion irradiation, even at floating potential, can result in films with high defect densities and high compressive stresses.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast, multiply-charged metal-ion irradiation, even at floating potential, can result in films with high defect densities and high compressive stresses. 2,3 Synchronized-bias HIPIMS CrN films deposited in mixed Ar/N2…”

Section: Introductionmentioning

confidence: 99%

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Strategy for tuning the average charge state of metal ions incident at the growing film during HIPIMS deposition

Greczyński

Petrov

Greene

et al. 2015

Vacuum

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Energy-and time-dependent mass spectrometry is used to determine the relative number density of singly-and multiply-charged metal-ion fluxes incident at the substrate during highpower pulsed magnetron sputtering (HIPIMS) as a function of the average noble-gas ionization potential. Ti is selected as the sputtering target since the microstructure, phase composition, properties, and stress-state of Ti-based ceramic thin films grown by HIPIMS are known to be strongly dependent on the charge state of Ti n+ (n = 1, 2, …) ions incident at the film growth surface.We find that the flux of Ti n+ with n > 2 is insignificant; thus, we measure the Ti 2+ /Ti + integrated flux ratio / at the substrate position as a function of the choice of noble gas --Ne, Ar, Kr, Xe, as well as Ne/Ar, Kr/Ar, and Xe/Ar mixtures --supporting the plasma. We demonstrate that by changing noble-gas mixtures, varies by more than two orders of magnitude with only a small change in . This allows the ratio / to be continuously tuned from less than 0.01 with Xe, which has a low first-ionization potential , to 0.62 with Ne which has a high . The value for Xe, = 12.16 eV, is larger than the first ionization potential of Ti, = 6.85 eV, but less than the second Ti ionization potential, = 13.62 eV. For Ne, however, = 21.63 eV is greater than both and . Therefore, the high-energy tail of the plasma-electron energy distribution can be systematically adjusted, allowing / to be controllably varied over a very wide range.corresponding author: grzgr@ifm.liu.se; phone: +46 13 28 1213

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Structural Stabilization and Piezoelectric Enhancement in Epitaxial (Ti₁₋_xMg_x)_0.25Al_0.75N(0001) Layers

Wang

Aryana

Gaskins

et al. 2020

Adv Funct Materials

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Epitaxial (Ti 1−x Mg x ) 0.25 Al 0.75 N(0001)/Al 2 O 3 (0001) layers are used as a model system to explore how Fermi-level engineering facilitates structural stabilization of a host matrix despite the intentional introduction of local bonding instabilities that enhance the piezoelectric response. The destabilizing octahedral bonding preference of Ti dopants and the preferred 0.67 nitrogen-to-Mg ratio for Mg dopants deteriorate the wurtzite AlN matrix for both Ti-rich (x < 0.2) and Mg-rich (x ≥ 0.9) alloys. Conversely, x = 0.5 leads to a stability peak with a minimum in the lattice constant ratio c/a which is caused by a Fermi-level shift into the bandgap and a trend towards non-directional ionic bonding, leading to a maximum in the expected piezoelectric stress constant e 33 . The refractive index and the sub-gap absorption decrease with x, the optical band gap increases, and the elastic constant along the hexagonal axis C 33 = 270±14 GPa remains composition independent, leading to an expected piezoelectric constant d 33 = 6.4 pC/N at x = 0.5 which is 50% larger than for the pure AlN matrix. Thus, contrary to the typical anti-correlation between stability and electromechanical coupling, the (Ti 1−x Mg x ) 0.25 Al 0.75 N system exhibits simultaneous maxima in the structural stability and the piezoelectric response at x = 0.5.

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Role of Tin+ and Aln+ ion irradiation (n=1, 2) during Ti1-xAlxN alloy film growth in a hybrid HIPIMS/magnetron mode

Cited by 126 publications

References 35 publications

Direct current magnetron sputtered ZrB2 thin films on 4H-SiC(0001) and Si(100)

Direct current magnetron sputtered ZrB2 thin films on 4H-SiC(0001) and Si(100)

Strategy for tuning the average charge state of metal ions incident at the growing film during HIPIMS deposition

Structural Stabilization and Piezoelectric Enhancement in Epitaxial (Ti₁₋_xMg_x)_0.25Al_0.75N(0001) Layers

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Role of Tin+ and Aln+ ion irradiation (n=1, 2) during Ti1-xAlxN alloy film growth in a hybrid HIPIMS/magnetron mode

Cited by 126 publications

References 35 publications

Direct current magnetron sputtered ZrB2 thin films on 4H-SiC(0001) and Si(100)

Direct current magnetron sputtered ZrB2 thin films on 4H-SiC(0001) and Si(100)

Strategy for tuning the average charge state of metal ions incident at the growing film during HIPIMS deposition

Structural Stabilization and Piezoelectric Enhancement in Epitaxial (Ti1−xMgx)0.25Al0.75N(0001) Layers

Contact Info

Product

Resources

About

Structural Stabilization and Piezoelectric Enhancement in Epitaxial (Ti₁₋_xMg_x)_0.25Al_0.75N(0001) Layers