Graphenea are known for pushing the barriers of graphene research. They have recently developed a Graphene FET (GFET) which is ready for immediate functionalization. This will save valuable research time and eliminate human error, making graphene research simpler and more efficient.
The origin of the field of nanotechnology to a famous lecture given by visionary physicist Richard Feynman back in 1959, entitled “There’s Plenty of Room At The Bottom,” – although at the time, the talk was considered speculative.
In order for it to be used in biosensor applications graphene must be modified to be blood compatible. Research in this area is currently taking place.
Nanotechnology is a branch of science dealing with the very small, smaller than the width of a human hair. But how can the very small be applied to the massive world of sports and can it really make the difference between winning and losing?
Materials with Similar Properties of Graphene
By Liji Thomas
Nanotechnology and Biotechnology - Similarities and Differences
Sport and nanotechnology: are the big sports looking to go small?
By Kerry Taylor-Smith
Is Nanotechnology Found in Food?
By Saransh Wales Maurya
How Does Nanotechnology Impact Medicine?
By Benedette Cuffari
What is Nanochemistry?
Tunable Optical Phenomenon in Graphene Could Lead to New Technologies
PF-SNOM Characterization Technique Reveals 3D Shape of Polariton Interaction Around Nanostructures
New Method Manipulates Electrical Conductivity of Graphene with Pressure
New Transmission Electron Microscopy Method Establishes 3D Position of Individual Atoms
Looking to Organic Molecular Nanowires for Miniaturization of Electronic Devices
Nanomaterials Can Preserve Precious Works of Art
Nanoengineering Stronger Materials
Researchers Control Transport of Polyelectrolyte Molecule Through Protein Channel
In this interview Brian O'Connor speaks to AZoNano about how piezo controller design influences thermal stability.
Prof. Antje J. Baeumner
Novel Nanomaterials for improved food safety.
The Graphene Field Effect Transistors (GFETs) from Graphenea are designed exclusively for handling sensing applications.
The Helios G4 PFIB enables breakthroughs in innovation with DualBeam™ technology. It delivers unrivalled capabilities for large volume 3D characterization and is able to handle Ga+ free sample preparation and precise micromachining quickly and easily.
QPAC® 60 is made up of no less than 94% Poly(butylene carbonate) polymer and has less than 5% butylene carbonate and less than 1% (between 0.2%-0.8%) methylene chloride.
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