Photocurrent of a single photosynthetic protein

Daniel Gerster; Joachim Reichert; Hai Bi; Johannes V. Barth; Simone M. Kaniber; Alexander W. Holleitner; Iris Visoly-Fisher; Shlomi Sergani; Itai Carmeli

doi:10.1038/nnano.2012.165

Photocurrent of a single photosynthetic protein

Daniel Gerster, Joachim Reichert, Hai Bi, Johannes V. Barth, Simone M. Kaniber, Alexander W. Holleitner, Iris Visoly-Fisher, Shlomi Sergani, Itai Carmeli

Ben-Gurion University of the Negev, Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

Photosynthesis is used by plants, algae and bacteria to convert solar energy into stable chemical energy. The initial stages of this process-where light is absorbed and energy and electrons are transferred-are mediated by reaction centres composed of chlorophyll and carotenoid complexes. It has been previously shown that single small molecules can be used as functional components in electric and optoelectronic circuits, but it has proved difficult to control and probe individual molecules for photovoltaic and photoelectrochemical applications. Here, we show that the photocurrent generated by a single photosynthetic protein-photosystem I-can be measured using a scanning near-field optical microscope set-up. One side of the protein is anchored to a gold surface that acts as an electrode, and the other is contacted by a gold-covered glass tip. The tip functions as both counter electrode and light source. A photocurrent of ∼10Â pA is recorded from the covalently bound single-protein junctions, which is in agreement with the internal electron transfer times of photosystem I.

Original language	American English
Pages (from-to)	673-676
Number of pages	4
Journal	Nature Nanotechnology
Volume	7
Issue number	10
DOIs	https://doi.org/10.1038/nnano.2012.165
State	Published - 26 Aug 2012

All Science Journal Classification (ASJC) codes

Bioengineering
Atomic and Molecular Physics, and Optics
Biomedical Engineering
General Materials Science
Condensed Matter Physics
Electrical and Electronic Engineering

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1038/nnano.2012.165

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title = "Photocurrent of a single photosynthetic protein",

abstract = "Photosynthesis is used by plants, algae and bacteria to convert solar energy into stable chemical energy. The initial stages of this process-where light is absorbed and energy and electrons are transferred-are mediated by reaction centres composed of chlorophyll and carotenoid complexes. It has been previously shown that single small molecules can be used as functional components in electric and optoelectronic circuits, but it has proved difficult to control and probe individual molecules for photovoltaic and photoelectrochemical applications. Here, we show that the photocurrent generated by a single photosynthetic protein-photosystem I-can be measured using a scanning near-field optical microscope set-up. One side of the protein is anchored to a gold surface that acts as an electrode, and the other is contacted by a gold-covered glass tip. The tip functions as both counter electrode and light source. A photocurrent of ∼10{\^A} pA is recorded from the covalently bound single-protein junctions, which is in agreement with the internal electron transfer times of photosystem I.",

author = "Daniel Gerster and Joachim Reichert and Hai Bi and Barth, {Johannes V.} and Kaniber, {Simone M.} and Holleitner, {Alexander W.} and Iris Visoly-Fisher and Shlomi Sergani and Itai Carmeli",

note = "Funding Information: This work was supported by the DFG via SPP 1243 (grants HO 3324/2 and RE 2592/2), COST-Phototech, the China Scholarship Council, the Nanosystems Initiative Munich (NIM), the Munich Center for Advanced Photonics (MAP), ERC Advanced Grant MolArt (no. 47299) and the Center of NanoScience (CeNS) in Munich. The authors thank A. Brenneis for technical assistance.",

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AU - Gerster, Daniel

AU - Reichert, Joachim

AU - Bi, Hai

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AU - Kaniber, Simone M.

AU - Holleitner, Alexander W.

AU - Visoly-Fisher, Iris

AU - Sergani, Shlomi

AU - Carmeli, Itai

N1 - Funding Information: This work was supported by the DFG via SPP 1243 (grants HO 3324/2 and RE 2592/2), COST-Phototech, the China Scholarship Council, the Nanosystems Initiative Munich (NIM), the Munich Center for Advanced Photonics (MAP), ERC Advanced Grant MolArt (no. 47299) and the Center of NanoScience (CeNS) in Munich. The authors thank A. Brenneis for technical assistance.

PY - 2012/8/26

Y1 - 2012/8/26

N2 - Photosynthesis is used by plants, algae and bacteria to convert solar energy into stable chemical energy. The initial stages of this process-where light is absorbed and energy and electrons are transferred-are mediated by reaction centres composed of chlorophyll and carotenoid complexes. It has been previously shown that single small molecules can be used as functional components in electric and optoelectronic circuits, but it has proved difficult to control and probe individual molecules for photovoltaic and photoelectrochemical applications. Here, we show that the photocurrent generated by a single photosynthetic protein-photosystem I-can be measured using a scanning near-field optical microscope set-up. One side of the protein is anchored to a gold surface that acts as an electrode, and the other is contacted by a gold-covered glass tip. The tip functions as both counter electrode and light source. A photocurrent of ∼10Â pA is recorded from the covalently bound single-protein junctions, which is in agreement with the internal electron transfer times of photosystem I.

AB - Photosynthesis is used by plants, algae and bacteria to convert solar energy into stable chemical energy. The initial stages of this process-where light is absorbed and energy and electrons are transferred-are mediated by reaction centres composed of chlorophyll and carotenoid complexes. It has been previously shown that single small molecules can be used as functional components in electric and optoelectronic circuits, but it has proved difficult to control and probe individual molecules for photovoltaic and photoelectrochemical applications. Here, we show that the photocurrent generated by a single photosynthetic protein-photosystem I-can be measured using a scanning near-field optical microscope set-up. One side of the protein is anchored to a gold surface that acts as an electrode, and the other is contacted by a gold-covered glass tip. The tip functions as both counter electrode and light source. A photocurrent of ∼10Â pA is recorded from the covalently bound single-protein junctions, which is in agreement with the internal electron transfer times of photosystem I.

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Photocurrent of a single photosynthetic protein

Abstract

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