TY - JOUR
T1 - Electron transport through two interacting channels in Azurin-based solid-state junctions
AU - Li, Ping'an
AU - Bera, Sudipta
AU - Kumar-Saxena, Shailendra
AU - Pecht, Israel
AU - Sheves, Mordechai
AU - Cahen, David
AU - Selzer, Yoram
N1 - Publisher Copyright:
© 2024 the Author(s).
PY - 2024/8/13
Y1 - 2024/8/13
N2 - The fundamental question of “what is the transport path of electrons through proteins?” initially introduced while studying long-range electron transfer between localized redox centers in proteins in vivo is also highly relevant to the transport properties of solid-state, dry metal–protein–metal junctions. Here, we report conductance measurements of such junctions, Au-(Azurin monolayer ensemble)-Bismuth (Bi) ones, with well-defined nanopore geometry and ~103 proteins/pore. Our results can be understood as follows. (1) Transport is via two interacting conducting channels, characterized by different spatial and time scales. The slow and spatially localized channel is associated with the Cu center of Azurin and the fast delocalized one with the protein’s polypeptide matrix. Transport via the slow channel is by a sequential (noncoherent) process and in the second one by direct, off-resonant tunneling. (2) The two channels are capacitively coupled. Thus, with a change in charge occupation of the weakly coupled (metal center) channel, the broad energy level manifold, responsible for off-resonance tunneling, shifts, relative to the electrodes’ Fermi levels. In this process, the off-resonance (fast) channel dominates transport, and the slow (redox) channel, while contributing only negligibly directly, significantly affects transport by intramolecular gating.
AB - The fundamental question of “what is the transport path of electrons through proteins?” initially introduced while studying long-range electron transfer between localized redox centers in proteins in vivo is also highly relevant to the transport properties of solid-state, dry metal–protein–metal junctions. Here, we report conductance measurements of such junctions, Au-(Azurin monolayer ensemble)-Bismuth (Bi) ones, with well-defined nanopore geometry and ~103 proteins/pore. Our results can be understood as follows. (1) Transport is via two interacting conducting channels, characterized by different spatial and time scales. The slow and spatially localized channel is associated with the Cu center of Azurin and the fast delocalized one with the protein’s polypeptide matrix. Transport via the slow channel is by a sequential (noncoherent) process and in the second one by direct, off-resonant tunneling. (2) The two channels are capacitively coupled. Thus, with a change in charge occupation of the weakly coupled (metal center) channel, the broad energy level manifold, responsible for off-resonance tunneling, shifts, relative to the electrodes’ Fermi levels. In this process, the off-resonance (fast) channel dominates transport, and the slow (redox) channel, while contributing only negligibly directly, significantly affects transport by intramolecular gating.
KW - (off)resonance
KW - bioelectronics
KW - capacitive interaction
KW - sequential
KW - tunneling
UR - http://www.scopus.com/inward/record.url?scp=85200939203&partnerID=8YFLogxK
U2 - 10.1073/pnas.2405156121
DO - 10.1073/pnas.2405156121
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C2 - 39110736
AN - SCOPUS:85200939203
SN - 0027-8424
VL - 121
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 33
M1 - e2405156121
ER -