Add to ORKGA protein-based solid-state electronic device that operates in air is reported; it is fabricated by interconnecting an azurin monolayer immobilized on SiO2 with two gold nanoelectrodes. The operating mechanism is ascribed to resonant tunneling through the redox active center, combined with macroscopic polarization of the oriented self-organized protein layer. The Figure shows the molecular electrostatic potential of the oxidized protein
The potential application of molecular switches as active elements in information storage has been d...
Molecular bioelectronics is a rapidly growing field at the junction of biochemistry, physics and sur...
Redox metalloproteins are emerging as promising candidates for future bio-optoelectronic and nano-bi...
A protein-based solid-state electronic device that operates in air is reported; it is fabricated by ...
A key challenge of the current research in nanoelectronics is the realization of biomolecular device...
We show that the electron-transfer protein azurin can be used to fabricate biomolecular rectifiers e...
In this work, we investigate the formation of redox protein Azurin (Az) monolayers on functionalized...
A key challenge in nanoelectronics is the use of a bottom-up approach to fabricate nanodevices from ...
A key challenge in nanoelectronics is the use of a bottom-up approach to fabricate nanodevices from ...
The rational design of azurin metalloprotein assemblies suitable for biomolecular electronics applic...
A protein field effect transistor (FET) exploiting the redox and self-assembly properties of the met...
A new type of transistor is presented. It is realised by using a metalloprotein; namely, azurin. Tha...
Metalloproteins are redox molecules naturally shuttling electrons with high efficiency between molec...
A new type of transistor is presented. It is realised by using a metalloprotein; namely,azurin. Than...
A key challenge of the current research in nanoelectronics is the realization of biomolecular device...
The potential application of molecular switches as active elements in information storage has been d...
Molecular bioelectronics is a rapidly growing field at the junction of biochemistry, physics and sur...
Redox metalloproteins are emerging as promising candidates for future bio-optoelectronic and nano-bi...
A protein-based solid-state electronic device that operates in air is reported; it is fabricated by ...
A key challenge of the current research in nanoelectronics is the realization of biomolecular device...
We show that the electron-transfer protein azurin can be used to fabricate biomolecular rectifiers e...
In this work, we investigate the formation of redox protein Azurin (Az) monolayers on functionalized...
A key challenge in nanoelectronics is the use of a bottom-up approach to fabricate nanodevices from ...
A key challenge in nanoelectronics is the use of a bottom-up approach to fabricate nanodevices from ...
The rational design of azurin metalloprotein assemblies suitable for biomolecular electronics applic...
A protein field effect transistor (FET) exploiting the redox and self-assembly properties of the met...
A new type of transistor is presented. It is realised by using a metalloprotein; namely, azurin. Tha...
Metalloproteins are redox molecules naturally shuttling electrons with high efficiency between molec...
A new type of transistor is presented. It is realised by using a metalloprotein; namely,azurin. Than...
A key challenge of the current research in nanoelectronics is the realization of biomolecular device...
The potential application of molecular switches as active elements in information storage has been d...
Molecular bioelectronics is a rapidly growing field at the junction of biochemistry, physics and sur...
Redox metalloproteins are emerging as promising candidates for future bio-optoelectronic and nano-bi...