Your search keyword '"Yang, Z. Y."' showing total 6 results

1. 3D porous framework of ZnO nanoparticles assembled from double carbon shells consisting of hard and soft carbon networks for high performance lithium ion batteries

Author

Zhang, X T, primary, Yuan, Y F, additional, Zhu, M, additional, Cai, G C, additional, Tong, Z W, additional, and Yang, Z Y, additional

Published

2020

2. Probing the location of displayed cytochrome b562on amyloid by scanning tunnelling microscopy

Author

Forman, C J, primary, Wang, N, additional, Yang, Z Y, additional, Mowat, C G, additional, Jarvis, S, additional, Durkan, C, additional, and Barker, P D, additional

Published

2013

3. Altering the ordering and disordering of a triangular nanographene at room temperature

Author

Wong, H S, primary, Feng, X, additional, Yang, Z Y, additional, Müllen, K, additional, Chandrasekhar, N, additional, and Durkan, C, additional

Published

2011

4. Probing the location of displayed cytochrome b562 on amyloid by scanning tunnelling microscopy.

Author

Forman, C. J., Wang, N., Yang, Z. Y., Mowat, C. G., Jarvis, S., Durkan, C., and Barker, P. D.

Subjects

CYTOCHROME b, AMYLOID, SCANNING tunneling microscopy, CHARGE exchange, HEME, COFACTORS (Biochemistry), GENETIC engineering

Abstract

Amyloid fibres displaying cytochrome b562 were probed using scanning tunnelling microscopy (STM) in vacuo. The cytochromes are electron transfer proteins containing a haem cofactor and could, in principle, mediate electron transfer between the tip and the gold substrate. If the core fibres were insulating and electron transfer within the 3D haem network was detected, then the electron transport properties of the fibre could be controlled by genetic engineering. Three kinds of STM images were obtained. At a low bias (<1:5 V) the fibres appeared as regions of low conductivity with no evidence of cytochrome mediated electron transfer. At a high bias, stable peaks in tunnelling current were observed for all three fibre species containing haem and one species of fibre that did not contain haem. In images of this kind, some of the current peaks were collinear and spaced around 10 nm apart over ranges longer than 100 nm, but background monomers complicate interpretation. Images of the third kind were rare (1 in 150 fibres); in these, fully conducting structures with the approximate dimensions of fibres were observed, suggesting the possibility of an intermittent conduction mechanism, for which a precedent exists in DNA. To test the conductivity, some fibres were immobilized with sputtered gold, and no evidence of conduction between the grains of gold was seen. In control experiments, a variation of monomeric cytochrome b562 was not detected by STM, which was attributed to low adhesion, whereas a monomeric multi-haem protein, GSU1996, was readily imaged. We conclude that the fibre superstructure may be intermittently conducting, that the cytochromes have been seen within the fibres and that they are too far apart for detectable current flow between sites to occur. We predict that GSU1996, being 10 nm long, is more likely to mediate successful electron transfer along the fibre as well as being more readily detectable when displayed from amyloid. [ABSTRACT FROM AUTHOR]

Published

2013

5. Probing the location of displayed cytochrome b562 on amyloid by scanning tunnelling microscopy.

Author

Forman CJ, Wang N, Yang ZY, Mowat CG, Jarvis S, Durkan C, and Barker PD

Subjects

Cytochrome b Group chemistry, Cytochrome c Group chemistry, Cytochrome c Group ultrastructure, Electric Conductivity, Geobacter chemistry, Geobacter enzymology, Models, Molecular, Amyloid chemistry, Amyloid ultrastructure, Cytochrome b Group ultrastructure, Microscopy, Scanning Tunneling methods

Abstract

Amyloid fibres displaying cytochrome b562 were probed using scanning tunnelling microscopy (STM) in vacuo. The cytochromes are electron transfer proteins containing a haem cofactor and could, in principle, mediate electron transfer between the tip and the gold substrate. If the core fibres were insulating and electron transfer within the 3D haem network was detected, then the electron transport properties of the fibre could be controlled by genetic engineering. Three kinds of STM images were obtained. At a low bias (<1.5 V) the fibres appeared as regions of low conductivity with no evidence of cytochrome mediated electron transfer. At a high bias, stable peaks in tunnelling current were observed for all three fibre species containing haem and one species of fibre that did not contain haem. In images of this kind, some of the current peaks were collinear and spaced around 10 nm apart over ranges longer than 100 nm, but background monomers complicate interpretation. Images of the third kind were rare (1 in 150 fibres); in these, fully conducting structures with the approximate dimensions of fibres were observed, suggesting the possibility of an intermittent conduction mechanism, for which a precedent exists in DNA. To test the conductivity, some fibres were immobilized with sputtered gold, and no evidence of conduction between the grains of gold was seen. In control experiments, a variation of monomeric cytochrome b562 was not detected by STM, which was attributed to low adhesion, whereas a monomeric multi-haem protein, GSU1996, was readily imaged. We conclude that the fibre superstructure may be intermittently conducting, that the cytochromes have been seen within the fibres and that they are too far apart for detectable current flow between sites to occur. We predict that GSU1996, being 10 nm long, is more likely to mediate successful electron transfer along the fibre as well as being more readily detectable when displayed from amyloid.

Published

2013

6. Altering the ordering and disordering of a triangular nanographene at room temperature.

Author

Wong HS, Feng X, Yang ZY, Müllen K, Chandrasekhar N, and Durkan C

Abstract

Molecular self-organization has the potential to serve as an efficient and versatile tool for the spontaneous creation of low-dimensional nanostructures on surfaces. We demonstrate how the subtle balance between intermolecular interactions and molecule-surface interactions can be altered by modifying the environment or through manipulation by means of the tip in a scanning tunnelling microscope (STM) at room temperature. We show how this leads to the distinctive ordering and disordering of a triangular nanographene molecule, the trizigzag-hexa-peri-hexabenzocoronenes-phenyl-6 (trizigzagHBC-Ph6), on two different surfaces: graphite and Au(111). The assembly of submonolayer films on graphite reveals a sixfold packing symmetry under UHV conditions, whereas at the graphite-phenyloctane interface, they reorganize into a fourfold packing symmetry, mediated by the solvent molecules. On Au(111) under UHV conditions in the multilayer films we investigated, although disorder prevails with the molecules being randomly distributed, their packing behaviour can be altered by the scanning motion of the tip. The asymmetric diode-like current-voltage characteristics of the molecules are retained when deposited on both substrates. This paper highlights the importance of the surrounding medium and any external stimulus in influencing the molecular organization process, and offers a unique approach for controlling the assembly of molecules at a desired location on a substrate.

Published

2012