Irinder S. Chopra scite author profile

Activation of molecular hydrogen is the first step in producing many important industrial chemicals that have so far required expensive noble-metal catalysts and thermal activation. We demonstrate here that aluminium doped with very small amounts of titanium can activate molecular hydrogen at temperatures as low as 90 K. Using an approach that uses CO as a probe molecule, we identify the atomistic arrangement of the catalytically active sites containing Ti on Al(111) surfaces, combining infrared reflection-absorption spectroscopy and first-principles modelling. CO molecules, selectively adsorbed on catalytically active sites, form a complex with activated hydrogen that is removed at remarkably low temperatures (115 K; possibly as a molecule). These results provide the first direct evidence that Ti-doped Al can carry out the essential first step of molecular hydrogen activation under nearly barrierless conditions, thereby challenging the monopoly of noble metals in hydrogen activation.

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Si₂H₆ Dissociative Chemisorption and Dissociation on Si(100)-(2×1) and Ge(100)-(2×1)

Veyan

Choi

Huang

et al. 2011

J. Phys. Chem. C

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Investigation of LiAlH4–THF formation by direct hydrogenation of catalyzed Al and LiH

Lacina

Liu

Chopra

et al. 2012

Phys. Chem. Chem. Phys.

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The formation of LiAlH(4)-THF by direct hydrogenation of Al and LiH in tetrahydrofuran (THF) was investigated using spectroscopic and computational methods. The molecular structures and free energies of the various possible adducts (THF-AlH(3), THF-LiH and THF-LiAlH(4)) present in a LiAlH(4)/THF solution were calculated and the dominant species were determined to be contact ion pairs where three THF molecules coordinate the lithium. Raman and X-ray absorption spectroscopy were used to investigate the effect of different Ti precursors on the formation of Al-H species and LiAlH(4)-THF and determine the optimal reaction conditions. A unique sample stage was developed from a microfluidic cell to evaluate the catalysts in situ. The effectiveness of two types of catalysts, titanium chloride (TiCl(3)) and titanium butoxide (Ti(C(4)H(9)O)(4)), and the catalyst concentration were evaluated under similar reaction conditions. Both catalysts were effective at facilitating hydrogenation, although TiCl(3) was more effective over the first few cycles with the greatest kinetic enhancement achieved with a low concentration of around 0.15 mol%. These results were qualitatively supported by infrared spectroscopy, which indicated that although a small amount of Ti is necessary for disassociating H(2), excess surface Ti (>0.1 ML) hinders the formation of Al-H species.

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Effect of Titanium Doping of Al(111) Surfaces on Alane Formation, Mobility, and Desorption

Chopra¹,

Chaudhuri²,

Veyan³

et al. 2011

J. Phys. Chem. C

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Erratum: Turning aluminium into a noble-metal-like catalyst for low-temperature activation of molecular hydrogen

Chopra¹,

Chaudhuri²,

Veyan³

et al. 2011

Nature Mater

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Irinder S. Chopra

Turning aluminium into a noble-metal-like catalyst for low-temperature activation of molecular hydrogen

Si₂H₆ Dissociative Chemisorption and Dissociation on Si(100)-(2×1) and Ge(100)-(2×1)

Investigation of LiAlH4–THF formation by direct hydrogenation of catalyzed Al and LiH

Effect of Titanium Doping of Al(111) Surfaces on Alane Formation, Mobility, and Desorption

Erratum: Turning aluminium into a noble-metal-like catalyst for low-temperature activation of molecular hydrogen

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Irinder S. Chopra

Turning aluminium into a noble-metal-like catalyst for low-temperature activation of molecular hydrogen

Si2H6 Dissociative Chemisorption and Dissociation on Si(100)-(2×1) and Ge(100)-(2×1)

Investigation of LiAlH4–THF formation by direct hydrogenation of catalyzed Al and LiH

Effect of Titanium Doping of Al(111) Surfaces on Alane Formation, Mobility, and Desorption

Erratum: Turning aluminium into a noble-metal-like catalyst for low-temperature activation of molecular hydrogen

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Product

Resources

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Si₂H₆ Dissociative Chemisorption and Dissociation on Si(100)-(2×1) and Ge(100)-(2×1)