[HTML][HTML] Enhancing the thermoelectric figure of merit in engineered graphene nanoribbons
H Sadeghi, S Sangtarash… - Beilstein journal of …, 2015 - beilstein-journals.org
Beilstein journal of nanotechnology, 2015•beilstein-journals.org
We demonstrate that thermoelectric properties of graphene nanoribbons can be dramatically
improved by introducing nanopores. In monolayer graphene, this increases the electronic
thermoelectric figure of merit ZT e from 0.01 to 0.5. The largest values of ZT e are found
when a nanopore is introduced into bilayer graphene, such that the current flows from one
layer to the other via the inner surface of the pore, for which values as high as ZT e= 2.45 are
obtained. All thermoelectric properties can be further enhanced by tuning the Fermi energy …
improved by introducing nanopores. In monolayer graphene, this increases the electronic
thermoelectric figure of merit ZT e from 0.01 to 0.5. The largest values of ZT e are found
when a nanopore is introduced into bilayer graphene, such that the current flows from one
layer to the other via the inner surface of the pore, for which values as high as ZT e= 2.45 are
obtained. All thermoelectric properties can be further enhanced by tuning the Fermi energy …
Abstract
We demonstrate that thermoelectric properties of graphene nanoribbons can be dramatically improved by introducing nanopores. In monolayer graphene, this increases the electronic thermoelectric figure of merit ZT e from 0.01 to 0.5. The largest values of ZT e are found when a nanopore is introduced into bilayer graphene, such that the current flows from one layer to the other via the inner surface of the pore, for which values as high as ZT e= 2.45 are obtained. All thermoelectric properties can be further enhanced by tuning the Fermi energy of the leads.
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