where he has worked since 1993. He received his Ph.D. in Solid State Physics in 1982 and his D.Sc. in Theoretical Physics in 1998. His research covers solid state physics, the physics of liquids, theory of adsorption, many-particle physics and the theory of electrochemical electron transfer. His present research is focused on the theory of electron tunneling in bridged electrochemical contacts. He is the author or co-author of more than 60 publications in scientific journals. Qijin Chi received his Ph.D. degree in analytical and physical chemistry in 1994 from the Changchun Institute of Applied Chemistry, Chinese Academy of Sciences. After having spent one year as a DFG postdoctoral fellow at Tübingen University, Germany, and two years as a JSPS postdoctoral fellow in Tokyo, Japan, he joined the Department of Chemistry at Technical University of Denmark in 1998. He is currently a lektor (associate professor) in chemistry. Qijin Chi also studied molecular biology and biochemistry (2000-2003) at the Johns Hopkins University School of Medicine. His research interests include biological nanomaterials, electrochemistry, surface self-assembled chemistry, and biophysics. He has authored four patents, over fifty research articles, and several book chapters. Tim Albrecht graduated in chemistry at the University of Essen in 2000. He received a Ph.D. with Prof. P. Hildebrandt at the Max-Planck Institute for Radiation Chemistry (now Bioinorganic Chemistry) in Muelheim/ Germany for studies on interfacial charge transfer processes of heme proteins using spectroelectrochemistry (SE(R)RS) and electrochemical STM. He held a Marie-Curie fellowship 2004-2006 whilst working in Prof. J. Ulstrup's group and became a lecturer in Physical Chemistry at Imperial College London in 2006. His research interests include (bio)electrochemistry, charge transport through individual molecules, and electrode/nanopore architectures in single-biomolecule sensing. He has published 14 research articles, 2 book chapters, and filed 2 patent applications. Palle Skovhus Jensen obtained his M.Sc. degree in 2006 at Technical University of Denmark and is presently a Ph.D. student in Prof. J. Ulstrup's group. His research includes interfacial electrochemistry, electrochemical STM and AFM of redox metalloproteins, extending to catalysis of bioelectrochemical processes by molecular scale metallic nanoparticles. He is the co-author of several research articles in these areas.
We have shown that Pseudomonas aeruginosa azurin can be immobilized on alkanethiol monolayers self-assembled on Au(111). Immobilization is achieved through hydrophobic interactions between the hydrophobic area around the copper atom in azurin and methyl heads of alkanethiol to form submonolayers or monolayers. In this orientation mode azurin molecules on Au(111) are oriented with the redox center (copper atom) facing the electrode surface. This is opposite to the orientation of azurin on bare gold which is via a surface disulfide group such as recently reported. Scanning tunneling microscopy (STM) with molecular resolution reveals that both well-ordered alkanethiol and protein adlayers are present. Adsorbed azurin molecules exhibit high stability and retain electron transfer (ET) function. Long-range interfacial ET between azurin and Au(111) across variable-length alkanethiol bridges was systematically investigated by different electrochemical techniques. Distance-dependent ET can be controlled by adjusting the length of the alkanethiol chain. The electrochemical ET rate constant is almost independent of the chain length up to ca. 9 methylene units but follows exponential distance decay with a decay factor (β) of 1.03 ± 0.02 per CH2 unit at longer chain lengths. Overvoltage-dependent ET was also examined. The results provide a strategy to ordered molecular assemblies, and controlled orientation and ET of azurin at atomically planar metallic surfaces. This approach can in principle be extended to other redox metalloproteins.
We provide a comprehensive approach to the formation and characterization of molecular monolayers of the blue copper protein Pseudomonas aeruginosa azurin on Au(111) in aqueous ammonium acetate solution. Main issues are adsorption patterns, reductive desorption, properties of the double layer, and long-range electrochemical electron transfer between the electrode and the copper center. Voltammetry, electrochemical impedance spectroscopy (EIS), in situ scanning tunneling microscopy (STM), and X-ray photoelectron spectroscopy (XPS) have been employed to disclose features of these issues. Zn-substituted azurin, cystine, and 1-butanethiol are investigated for comparison. Cyclic voltammetric and capacitance measurements show qualitatiVely that azurin is adsorbed at submicromolar concentrations over a broad potential range. The characteristics of reductive desorption suggest that azurin is adsorbed via its disulfide group to form a monolayer. The adsorption of this protein on Au(111) via a gold-sulfur binding mode is further supported by XPS measurements. In situ STM images with molecular resolution have been recorded and show a dense monolayer organization of adsorbed azurin molecules. Direct electron transfer (ET) between the copper atom of adsorbed azurin and the electrode has been revealed by differential pulse voltammetry. The rate constant is estimated from electrochemical impedance spectroscopy and shows that ET is compatible with a long-range ET mode such as that anticipated by theoretical frames. The results constitute the first case of an electrochemically functional redox protein monolayer at single-crystal metal electrodes.
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