Graphene is a suitable material for future sensors and biosensors due to its high sensitivity to the presence of adsorbents, low thermal noise, and biocompatibility. This work focuses on the lateral shaping of graphene on SiO2 using atomic force microscope-based mechanical lithography. The created barriers exhibit resistances on the order of hundreds of G and are applicable for nanosensor fabrication. Charge propagation is studied in this work through concurrent measurements of Kelvin probe force microscopy and macroscopic transport measurements at various humidities, corresponding to real conditions of atmospheric or solution-based sensors and biosensors
International audienceConducting Probe Atomic Force Microscopy (CP-AFM) has been used to perform mec...
Máster en Materiales Nanoestructurados para Aplicaciones Nanotecnológicas (Nanostructured Materials ...
Patterning graphene into various mesoscopic devices such as nanoribbons, quantum dots, etc. by litho...
This thesis presents a novel approach to integrate chemical vapor deposition (CVD) graphene into sil...
Graphene is a material suitable for electronic applications including sensors and biosensors operati...
We have fabricated graphene/graphene oxide/graphene (G/GO/G) junctions by local anodic oxidation lit...
Alternative lithographic techniques, in particular those based on scanning probe microscopy, have sh...
We have developed a novel technique for fabrication of nanopores in suspended graphene (SG) films us...
The contact resistance is a key bottleneck limiting the performance of graphene-based electronic and...
We demonstrate the local oxidation nanopatterning of graphene films by an atomic for...
This thesis is not available on this repository until the author agrees to make it public. If you ar...
Táto bakalárska práca je o testovaní možnosti a účinnosti použitia mechanickej litografie pomocou mi...
After one decade of analyzing the intrinsic properties of graphene, interest into the development of...
Scanning probe techniques scanning tunneling microscopy (STM) and atomic force microscopy (AFM) have...
Graphene, an atomically-thin layer of hexagonally bonded carbon atoms, is the strongest material eve...
International audienceConducting Probe Atomic Force Microscopy (CP-AFM) has been used to perform mec...
Máster en Materiales Nanoestructurados para Aplicaciones Nanotecnológicas (Nanostructured Materials ...
Patterning graphene into various mesoscopic devices such as nanoribbons, quantum dots, etc. by litho...
This thesis presents a novel approach to integrate chemical vapor deposition (CVD) graphene into sil...
Graphene is a material suitable for electronic applications including sensors and biosensors operati...
We have fabricated graphene/graphene oxide/graphene (G/GO/G) junctions by local anodic oxidation lit...
Alternative lithographic techniques, in particular those based on scanning probe microscopy, have sh...
We have developed a novel technique for fabrication of nanopores in suspended graphene (SG) films us...
The contact resistance is a key bottleneck limiting the performance of graphene-based electronic and...
We demonstrate the local oxidation nanopatterning of graphene films by an atomic for...
This thesis is not available on this repository until the author agrees to make it public. If you ar...
Táto bakalárska práca je o testovaní možnosti a účinnosti použitia mechanickej litografie pomocou mi...
After one decade of analyzing the intrinsic properties of graphene, interest into the development of...
Scanning probe techniques scanning tunneling microscopy (STM) and atomic force microscopy (AFM) have...
Graphene, an atomically-thin layer of hexagonally bonded carbon atoms, is the strongest material eve...
International audienceConducting Probe Atomic Force Microscopy (CP-AFM) has been used to perform mec...
Máster en Materiales Nanoestructurados para Aplicaciones Nanotecnológicas (Nanostructured Materials ...
Patterning graphene into various mesoscopic devices such as nanoribbons, quantum dots, etc. by litho...