Excellent Science INNOVATION
New pre-patterning method to fabricate constrictions in graphene flakes.
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Market Maturity: Exploring
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Market Creation Potential
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Go to Market needs
Needs that, if addressed, can increase the chances this innovation gets to (or closer to) the market incude:
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Location of Key Innovators developing this innovation
Key Innovators
TECHNISCHE UNIVERSITEIT DELFT
DELFT, NL
Higher Education Institute / Research Centre
UNIVERSITAET BERN
BERN, CH
Higher Education Institute / Research Centre
AGENCIA ESTATAL CONSEJO SUPERIOR DEINVESTIGACIONES CIENTIFICAS
MADRID, ES
Higher Education Institute / Research Centre
The EU-funded Research Project
This innovation was developed under the FP7 project ACMOL with an end date of 31/12/2016
  • Read more about this project on CORDIS
Description of Project ACMOL
The project “Electrical spin manipulation in electroACtive MOLecules” (ACMOL) has the ambitious goal of fabricating a switchable, room-temperature spin-polarizer employing electro-active and magnetic molecules, which are integrated into graphene-type electrodes modified with ferromagnetic materials. The combination of these molecules with ferromagnetic electrodes is a new route in spintronics. Exploiting the high stability of graphene, we aim to demonstrate for the first time good performance of the device at room temperature. The outstanding devices can be applied to a broad number of different technological and societal fields, such as high-density data storage, microelectronics, (bio)sensors, quantum computing and medical technologies. An external electric field will be applied to read and manipulate the state of the device, as well as its charge transport properties. The characterization of the electrical response will be carried out in a 3-terminal configuration composed of source, drain and gate. The charge transport properties of the molecular junctions will be investigated in a solid-state back-gate configuration, as well as in solution, employing an “electrolyte gate”. In this way, the devices will operate as switches that can be exploited to read and write information, which is stored in the oxidation and magnetic state of each molecule. The project involves the synthesis of the functional moieties, the device fabrication and characterization, as well as DFT modelling, which will be based on a fully quantitative description of the electronic structure at non-equilibrium. To accomplish the objectives of the project, we have chosen an interdisciplinary approach with four young research teams representing expertise in synthetic chemistry, molecular self-assembly, molecular-scale surface electrochemistry, device engineering, and DFT-based mesoscopic spin-transport calculations.

Innnovation Radar's analysis of this innovation is based on data collected on 13/02/2015.