Thomas J. Knisley scite author profile

Treatment of MCl 2 (M = Cr, Mn, Fe, Co, Ni) with 2 equiv of lithium metal and 1,4-di-tertbutyl-1,3-diazadiene ( tBu2 DAD) in tetrahydrofuran at ambient temperature afforded Cr( tBu2 DAD) 2 (38%), Mn( tBu2 DAD) 2 (81%), Fe( tBu2 DAD) 2 (47%), Co( tBu2 DAD) 2 (36%), and Ni( tBu2 DAD) 2 (41%). Crystal structure determinations revealed monomeric complexes that adopt tetrahedral coordination environments and were consistent with tBu2 DAD radical anion ligands. To evaluate the viability of M( tBu2 DAD) 2 (M = Cr, Mn, Fe, Co, Ni) as potential film growth precursors, thermogravimetric analyses, preparative sublimations, and solid-state decomposition studies were performed. Mn( tBu2 DAD) 2 is the most thermally robust among the series, with a solid-state decomposition temperature of 325 °C, a sublimation temperature of 120 °C/0.05 Torr, and a nonvolatile residue of 4.3% in a preparative sublimation. Thermogravimetric traces of all complexes show weight loss regimes from 150 to 225 °C with final percent residues at 500 °C ranging from 1.5 to 3.6%. Thermolysis studies reveal that all complexes except Mn( tBu2 DAD) 2 decompose into their respective crystalline metal powders under an inert atmosphere. Mn( tBu2 DAD) 2 may afford amorphous manganese metal upon thermolysis.

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Thermal atomic layer deposition of ruthenium metal thin films using nonoxidative coreactants

Cwik

Woods

Saly

et al. 2019

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Atomic layer deposition (ALD) of ruthenium metal films is presented using (η4-2,3-dimethylbutadiene)(tricarbonyl)ruthenium [Ru(DMBD)(CO)3] with the coreactants 1,1-dimethylhydrazine, hydrazine, or tert-butylamine. The dependence of growth rate on precursor pulse lengths at 200 °C showed a saturative, self-limited behavior at ≥3.0 s for Ru(DMBD)(CO)3 and ≥0.1 s for 1,1-dimethylhydrazine. An ALD window was observed from 200 to 210 °C, with a growth rate of 0.42 Å/cycle. Films grown at 200 °C showed rms surface roughnesses of <1 nm. X-ray photoelectron spectroscopy of a 42 nm thick film grown at 200 °C revealed 90.6% ruthenium, 7.0% nitrogen, and 2.0% oxygen. Ruthenium films were deposited on patterned substrates with TiN surfaces using various treatments at 200 °C with 250 cycles. 42 nm thick ruthenium films grown at 200 °C were subjected to annealing studies under hydrogen and ammonia atmospheres at 400 °C, followed by rapid thermal annealing at 600 °C. These annealing procedures led to higher purity, more crystalline, and lower resistivity ruthenium films. The coreactants hydrazine and tert-butylamine were evaluated in ruthenium ALD trials using Ru(DMBD)(CO)3. Hydrazine gave a growth rate of 0.42 Å/cycle within a 200–205 °C ALD window, whereas tert-butylamine gave a growth rate of 0.25 Å/cycle at 200 °C.

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Exceptional thermal stability and high volatility in mid to late first row transition metal complexes containing carbohydrazide ligands

Karunarathne¹,

Knisley²,

Tunstull³

et al. 2013

Polyhedron

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Thomas J. Knisley

Precursors and chemistry for the atomic layer deposition of metallic first row transition metal films

Low Temperature Growth of High Purity, Low Resistivity Copper Films by Atomic Layer Deposition

Volatility and High Thermal Stability in Mid- to Late-First-Row Transition-Metal Diazadienyl Complexes

Thermal atomic layer deposition of ruthenium metal thin films using nonoxidative coreactants

Exceptional thermal stability and high volatility in mid to late first row transition metal complexes containing carbohydrazide ligands

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