The research study has been included in the cover of the Journal of the American Chemical Society (JACS). Credit: Dr. Maria Tenorio and Dámaso Torres · ICN2.
The authors of this study synthesized a new nanoporous graphene structure by connecting ultra-narrow graphene strips, understood as “nanoribbons,” by methods of flexible “bridges” made from phenylene moieties (which are portions of bigger molecules). By modifying in a continuous way the architecture and angle of these bridges, the researchers can control the quantum connectivity in between the nanoribbon channels and, ultimately, fine-tune the electronic residential or commercial properties of the graphene nanoarchitecture. The tunability could likewise be controlled by external stimuli, such as stress or electrical fields, supplying chances for different applications.
These ground-breaking findings, arising from a cooperation between top-tier Spanish organizations (CiQUS, ICN2, University of Cantabria, DIPC) and the Technical University of Denmark (DTU), reveals that the proposed molecular bridge strategy can have a fantastic effect on the synthesis of brand-new products with customized homes and is an effective tool for the awareness of quantum circuits. These carry out operations similar to those of standard circuits, although unlike the latter, quantum circuits take advantage of quantum effects and phenomena. The design and implementation of these systems are exceptionally appropriate to the advancement of quantum computers.
However the prospective applications of the method proposed in this research study go beyond future electronic devices and computers. It might likewise lead to the advancement of thermoelectric nanomaterials, which can have a crucial effect in sustainable energy generation and waste heat healing, for that reason attending to another crucial societal challenge.
Reference: “Molecular Bridge Engineering for Tuning Quantum Electronic Transport and Anisotropy in Nanoporous Graphene” by César Moreno, Xabier Diaz de Cerio, Manuel Vilas-Varela, Maria Tenorio, Ane Sarasola, Mads Brandbyge, Diego Peña, Aran Garcia-Lekue and Aitor Mugarza, 29 March 2023, Journal of the American Chemical Society.DOI: 10.1021/ jacs.3 c00173.
By Center for Research Study in Biological Chemistry and Molecular Materials (CiQUS).
May 2, 2023.
In a considerable development, researchers have created a brand-new graphene nanostructure with adjustable homes by linking graphene strips using versatile “bridges.” This discovery has the possible to influence quantum computing and eco-friendly energy applications.
Envision having a structure made of stacks of bricks connected by adaptable bridges. You pull a knob that customizes the bridges and the structure changes functionality. Wouldnt it be fantastic?
A group of scientists led by Prof. Aitor Mugarza, from the Catalan Institute of Nanoscience and Nanotechnology (ICN2) and ICREA, together with Prof. Diego Peña from the Center for Research in Biological Chemistry and Molecular Materials of the University of Santiago de Campostela (CiQUS-USC), Dr Cesar Moreno, formerly a member of ICN2s team and presently a researcher at the University of Cantabria, and Dr Aran Garcia-Lekue, from the Donostia International Physics Center (DIPC) and Ikerbasque Foundation, has actually done something analogous, however at the single-atom scale, with the aim of manufacturing new carbon-based products with tunable properties.
As discussed in a paper just published in the Journal of the American Chemical Society (JACS) and included on the cover of the problem, this research is a substantial breakthrough in the precise engineering of atomic-thin products– called “2D materials” due to their minimized dimensionality. The proposed fabrication technique opens exciting brand-new possibilities for products science, and, in specific, for application in innovative electronics and future options for sustainable energy.
Researchers from CiQUS, ICN2, University of Cantabria, DIPC and DTU sign up with forces to develop a versatile approach for developing brick-by-brick carbon nanocircuits with tunable residential or commercial properties.
Possible applications include future electronic devices, circuits for quantum computer systems, and thermoelectric nanomaterials for renewable resource.
The authors of this study manufactured a brand-new nanoporous graphene structure by linking ultra-narrow graphene strips, known as “nanoribbons,” by methods of versatile “bridges” made of phenylene moieties (which are portions of bigger molecules). By customizing in a constant way the architecture and angle of these bridges, the scientists can control the quantum connectivity in between the nanoribbon channels and, ultimately, fine-tune the electronic homes of the graphene nanoarchitecture. These ground-breaking findings, resulting from a cooperation between top-tier Spanish organizations (CiQUS, ICN2, University of Cantabria, DIPC) and the Technical University of Denmark (DTU), shows that the proposed molecular bridge method can have a terrific impact on the synthesis of new products with customized properties and is an effective tool for the awareness of quantum circuits. These perform operations comparable to those of traditional circuits, although unlike the latter, quantum circuits utilize quantum results and phenomena.
