Pekka Lehtinen scite author profile

We present a density-functional-theory study of transition-metal atoms (Sc-Zn, Pt, and Au) embedded in single and double vacancies (SV and DV) in a graphene sheet. We show that for most metals, the bonding is strong and the metal-vacancy complexes exhibit interesting magnetic behavior. In particular, an Fe atom on a SV is not magnetic, while the Fe@DV complex has a high magnetic moment. Surprisingly, Au and Cu atoms at SV are magnetic. Both bond strengths and magnetic moments can be understood within a simple local-orbital picture, involving carbon sp 2 hybrids and the metal spd orbitals. We further calculate the barriers for impurity-atom migration, and they agree well with available experimental data. We discuss the experimental realization of such systems in the context of spintronics and nanocatalysis.

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Irradiation-Induced Magnetism in Graphite: A Density Functional Study

Lehtinen

et al. 2004

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Magnetic properties of vacancies in graphene and single-walled carbon nanotubes

et al. 2004

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Bending the rules: Contrasting vacancy energetics and migration in graphite and carbon nanotubes

Krasheninnikov

Lehtinen

Foster

et al. 2006

Chemical Physics Letters

322

258

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Bioprocessing of Wheat Bran Improves in vitro Bioaccessibility and Colonic Metabolism of Phenolic Compounds

Anson

Selinheimo

Havenaar

et al. 2009

J. Agric. Food Chem.

224

136

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Ferulic acid (FA) is the most abundant phenolic compound in wheat grain, mainly located in the bran. However, its bioaccessibility from the bran matrix is extremely low. Different bioprocessing techniques involving fermentation or enzymatic and fermentation treatments of wheat bran were developed aiming at improving the bioaccessibility of phenolic compounds in bran-containing breads. The bioaccessibility of ferulic acid, p-coumaric acid, and sinapic acid was assessed with an in vitro model of upper gastrointestinal tract (TIM-1). Colonic metabolism of the phenolic compounds in the nonbioaccessible fraction of the breads was studied with an in vitro model of human colon (TIM-2). The most effective treatment was the combination of enzymes and fermentation that increased the bioaccessibility of FA from 1.1% to 5.5%. The major colonic metabolites were 3-(3-hydroxyphenyl)propionic acid and 3-phenylpropionic acid. Bran bioprocessing increases the bioaccessibility of phenolic compounds as well as the colonic end metabolite 3-phenylpropionic acid.

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Pekka Lehtinen

Embedding Transition-Metal Atoms in Graphene: Structure, Bonding, and Magnetism

Irradiation-Induced Magnetism in Graphite: A Density Functional Study

Magnetic properties of vacancies in graphene and single-walled carbon nanotubes

Bending the rules: Contrasting vacancy energetics and migration in graphite and carbon nanotubes

Bioprocessing of Wheat Bran Improves in vitro Bioaccessibility and Colonic Metabolism of Phenolic Compounds

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