Robert J. Hamers scite author profile

Diamond, because of its electrical and chemical properties, may be a suitable material for integrated sensing and signal processing. But methods to control chemical or biological modifications on diamond surfaces have not been established. Here, we show that nanocrystalline diamond thin-films covalently modified with DNA oligonucleotides provide an extremely stable, highly selective platform in subsequent surface hybridization processes. We used a photochemical modification scheme to chemically modify clean, H-terminated nanocrystalline diamond surfaces grown on silicon substrates, producing a homogeneous layer of amine groups that serve as sites for DNA attachment. After linking DNA to the amine groups, hybridization reactions with fluorescently tagged complementary and non-complementary oligonucleotides showed no detectable non-specific adsorption, with extremely good selectivity between matched and mismatched sequences. Comparison of DNA-modified ultra-nanocrystalline diamond films with other commonly used surfaces for biological modification, such as gold, silicon, glass and glassy carbon, showed that diamond is unique in its ability to achieve very high stability and sensitivity while also being compatible with microelectronics processing technologies. These results suggest that diamond thin-films may be a nearly ideal substrate for integration of microelectronics with biological modification and sensing.

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Photo-illuminated diamond as a solid-state source of solvated electrons in water for nitrogen reduction

Zhu

et al. 2013

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The photocatalytic reduction of N₂ to NH₃ is typically hampered by poor binding of N₂ to catalytic materials and by the very high energy of the intermediates involved in this reaction. Solvated electrons directly introduced into the reactant solution can provide an alternative pathway to overcome such limitations. Here we demonstrate that illuminated hydrogen-terminated diamond yields facile electron emission into water, thus inducing reduction of N₂ to NH₃ at ambient temperature and pressure. Transient absorption measurements at 632 nm reveal the presence of solvated electrons adjacent to the diamond after photoexcitation. Experiments using inexpensive synthetic diamond samples and diamond powder show that photocatalytic activity is strongly dependent on the surface termination and correlates with the production of solvated electrons. The use of diamond to eject electrons into a reactant liquid represents a new paradigm for photocatalytic reduction, bringing electrons directly to reactants without requiring molecular adsorption to the surface.

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Highly active hydrogen evolution catalysis from metallic WS₂ nanosheets

Lukowski

Daniel

English

et al. 2014

Energy Environ. Sci.

676

516

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Synthesis and Characterization of DNA-Modified Silicon (111) Surfaces

et al. 2000

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surfaces are modified by attachment of oligodeoxynucleotides and characterized with respect to DNA surface density, chemical stability, and DNA hybridization binding specificity. Surface functionalization employs the reaction of ω-unsaturated alkyl esters with the Si(111) surface using UV irradiation. Cleavage of the ester using potassium tert-butoxide yields a carboxyl-modified surface, which serves as a substrate for the attachment of DNA by means of an electrostatically adsorbed layer of polylysine and attachment of thiol-modified DNA using a heterobifunctional cross-linker. The resultant DNA-modified surfaces are shown to exhibit excellent specificity and chemical stability under the conditions of DNA hybridization. This work provides an avenue for the development of devices in which the exquisite binding specificity of biomolecular recognition is directly coupled to semiconductor devices.

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Robert J. Hamers

DNA-modified nanocrystalline diamond thin-films as stable, biologically active substrates

Photo-illuminated diamond as a solid-state source of solvated electrons in water for nitrogen reduction

Highly active hydrogen evolution catalysis from metallic WS₂ nanosheets

Synthesis and Characterization of DNA-Modified Silicon (111) Surfaces

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About

Robert J. Hamers

DNA-modified nanocrystalline diamond thin-films as stable, biologically active substrates

Photo-illuminated diamond as a solid-state source of solvated electrons in water for nitrogen reduction

Highly active hydrogen evolution catalysis from metallic WS2 nanosheets

Synthesis and Characterization of DNA-Modified Silicon (111) Surfaces

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Product

Resources

About

Highly active hydrogen evolution catalysis from metallic WS₂ nanosheets