Nanoparticle and Powder Processing Services
Service Detail from Matexcel
Nanotechnology is a powerful tool in biomaterials research as it creates numerous possibilities for the engineering of functional molecules. Nano-Bio refers to projected ability to incorporate biomimicry into various materials at nanoscale. Recent progress in nanotechnology has enabled effective conjugation of bioactive molecules with nanomaterials, forming hybridized conjugates. Nanomaterials are multifunctional molecules formed the combination of metals, ceramics and polymers. Based on their structure, nanomaterials can be divided into nanoparticles, nanocomposites, and nanopatterned surfaces. At Matexcel, we provide the custom nanomaterials synthesis as well as surface modification with different molecules, e.g., synthesis of nanorods, bioconjugation of peptide on nanoparticles.
- Nanomaterial Synthesis
- Nanomaterials Characterization
- Nanoparticle Modification
- Surface Nanopatterning
As a molecular sheet of graphite, graphene is comprised of a single layer of carbon atoms set in a hexagonal lattice. It is the simplest structural element of different allotropes of carbon (graphite, carbon nanotubes, etc.) and it can be deliberated as an indeterminately huge aromatic molecule. Since its first isolation from graphite by two researchers at The University of Manchester, Prof. Andre Geim and Prof. Kostya Novoselov in 2004, graphene has undoubtedly emerged as one of the most promising nanomaterials because of its unique combination of superb mechanical, electrical and thermal properties. For example, graphene is the toughest material ever found and is nearly transparent. It also provides proficient heat and electrical conductivity. Graphene demonstrates a large and nonlinear diamagnetism, which is more than that of graphite, and can be ascended by neodymium magnets. Because of these extraordinary properties a great deal of interest is generated on the graphene research, including theoretical and experimental studies. Those studies open a way for graphene’s exploitation in a wide spectrum of applications ranging from electronics to optics, sensors, biodevices and energy-storage devices.
As mentioned above, graphene finds a great amount of applications during the past decade. However, its insolubility in most organic and inorganic solvents adversely impacts the potential for solution-phase processing. Chemical modification of graphene through covalent or non-covalent interactions to obtain new graphene derivatives has attracted a lot of interest. Graphene oxide (GO), derived from the oxidation of graphite, possesses abundant reactive oxygen functional groups, which not only render GO moderate water-dispersibility
Since various chemical modification reactions utilizing these oxygen-containing groups have been developed, doping is increasingly used as one of the most feasible methods to control the semiconducting properties of graphene. Herein, substantial effort has been made in both academia and industry, resulting in the recent burst of technologies in graphene doping, which is roughly divided into three categories: first, the hetero atom doping, including arc discharge, chemical vapor deposition, electrothermal reaction and ion-irradiation approaches; second, the chemical modification; third, the electrostatic field tuning. At Matexcel, our experts in graphene chemistry offer different strategies for graphene modification, including chemical modification, polymer grafting, and doping.