先进材料与技术溶液化学国际实验室
简介
Development of modern technologies is largely determined by the development of Material Sciences . Among the huge variety of existing materials and systems , preference is given to the most effective and inexpensive. Since the properties of modern materials are less dependent on the chemical composition and their value depends on the method of their production, the development of new synthetic methods not involving the use of expensive equipment , is the most promising direction of development of science and technology of the 21st century . Among these methods way of growing material a predetermined pattern and a composition in solution are successfully used.
One of the world leaders in this field of knowledge is David Avnir ( Hebrew University, Jerusalem, Israel) . His approval be co-director of the laboratory , high publication activity (h-index 65) , focus on the organization of joint educational programs and high entrepreneurial potential ( founder of Sol - Gel Technologies) are the key to the successful launch of MNL and its operation over the next years.
研究方向
The sol - gel materials for biochemical engineering
New hybrid materials for enzymatic biocatalysis.
Biocompatible hybrid sol - gel systems for the therapy of intractable diseases and medical diagnostics.
Interaction of proteins with sol - gel matrices of different chemical composition.
Protection of entrapped biological objects from the action of external physical and chemical effects by sol - gel matrix.
Artificial sol - gel biocoating for healing of the affected areas of the skin.
Hybrid sol - gel materials 3D - printing.
New sol - gel materials for semiconductor technology
Doped sol - gel systems for transparent and flexible supercapacitors and solar cells.
Preparation and application of new sol - gel films with high conductivity.
Soluted doped sol - gel systems for the needs of photonics and electronics controlled electrochemical self-assembly.
Functionalized nanoparticles and highly porous materials
Fabrication of new metal-organic frameworks (MOF) with a specific crystal porosities greater than 60%.
New diagnostics and highly porous nanoparticles preparation..
Combination of sol - gel methods and soft chemistry for different devices nanofabrication.
Low temperature sol - gel synthesis
Fundamental aspects of the formation and crystallization heterooxide systems at room temperature .
Doping of low-temperature crystal sol- gel materials low-temperature.
Low-temperature synthesis of hybrid sol - gel matrixes based on crystalline polymers and oxides with biomaterials.