TY - JOUR
T1 - Temperature-Dependent Coherent Tunneling across Graphene-Ferritin Biomolecular Junctions
AU - Gupta, Nipun Kumar
AU - Karuppannan, Senthil Kumar
AU - Pasula, Rupali Reddy
AU - Vilan, Ayelet
AU - Martin, Jens
AU - Xu, Wentao
AU - May, Esther Maria
AU - Pike, Andrew R.
AU - Astier, Hippolyte P.A.G.
AU - Salim, Teddy
AU - Lim, Sierin
AU - Nijhuis, Christian A.
N1 - Publisher Copyright:
© 2022 American Chemical Society. All rights reserved.
PY - 2022/10/5
Y1 - 2022/10/5
N2 - Understanding the mechanisms of charge transport (CT) across biomolecules in solid-state devices is imperative to realize biomolecular electronic devices in a predictive manner. Although it is well-Accepted that biomolecule-electrode interactions play an essential role, it is often overlooked. This paper reveals the prominent role of graphene interfaces with Fe-storing proteins in the net CT across their tunnel junctions. Here, ferritin (AfFtn-AA) is adsorbed on the graphene by noncovalent amine-graphene interactions confirmed with Raman spectroscopy. In contrast to junctions with metal electrodes, graphene has a vanishing density of states toward its intrinsic Fermi level ("Dirac point"), which increases away from the Fermi level. Therefore, the amount of charge carriers is highly sensitive to temperature and electrostatic charging (induced doping), as deduced from a detailed analysis of CT as a function of temperature and iron loading. Remarkably, the temperature dependence can be fully explained within the coherent tunneling regime due to excitation of hot carriers. Graphene is not only demonstrated as an alternative platform to study CT across biomolecular tunnel junctions, but it also opens rich possibilities in employing interface electrostatics in tuning CT behavior.
AB - Understanding the mechanisms of charge transport (CT) across biomolecules in solid-state devices is imperative to realize biomolecular electronic devices in a predictive manner. Although it is well-Accepted that biomolecule-electrode interactions play an essential role, it is often overlooked. This paper reveals the prominent role of graphene interfaces with Fe-storing proteins in the net CT across their tunnel junctions. Here, ferritin (AfFtn-AA) is adsorbed on the graphene by noncovalent amine-graphene interactions confirmed with Raman spectroscopy. In contrast to junctions with metal electrodes, graphene has a vanishing density of states toward its intrinsic Fermi level ("Dirac point"), which increases away from the Fermi level. Therefore, the amount of charge carriers is highly sensitive to temperature and electrostatic charging (induced doping), as deduced from a detailed analysis of CT as a function of temperature and iron loading. Remarkably, the temperature dependence can be fully explained within the coherent tunneling regime due to excitation of hot carriers. Graphene is not only demonstrated as an alternative platform to study CT across biomolecular tunnel junctions, but it also opens rich possibilities in employing interface electrostatics in tuning CT behavior.
KW - Biomolecular electronics
KW - Charge transport
KW - EGaIn
KW - Ferritin
KW - Graphene
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U2 - 10.1021/acsami.2c11263
DO - 10.1021/acsami.2c11263
M3 - Article
C2 - 36148983
AN - SCOPUS:85139367576
SN - 1944-8244
VL - 14
SP - 44665
EP - 44675
JO - ACS Applied Materials and Interfaces
JF - ACS Applied Materials and Interfaces
IS - 39
ER -