the advanced materials revolution - sap super absorbent polymer
Imagine what you can do with something stronger than steel and lighter than wood.
Or let you 3D print the material of the electronic circuit.
Or do a super
Fully transparent, conductive and water film-repellent.
3D laboratory of graphene (OTCQB:GPHBF)
The Advanced Materials Department is working with nano-graphene and other one-dimensional materials to truly create the future.
The graphene laboratory combines atomic thick materials with advanced 3D printing technology and complex hybrid solutions, allowing the performance of graphene and other one-dimensional materials to be transferred to existing materials.
The latest progress in the manufacture of nanotechnology and additives has promoted the revolution of Advanced Materials (3D printing).
Advances in nanotechnology have led to the discovery of graphene, a fascinating nano-material that has many records and is the strongest material in the world with the highest electrical and thermal conductivity.
Additive manufacturing provides a whole new dimension in the development of advanced materials, allowing the creation of materials with precise mathematical calculations of structures.
The structure can define the performance of the material: by combining the soft material with the hard material, the hardness of the material can be controlled.
Learning how to combine these materials is an important part of the intellectual property rights of graphene 3D labs.
Alternatively, ultra-light, high-absorption foam can be produced with graphene oxide and reduced graphene oxide.
The graphene 3D laboratory has announced that precise control of the mechanical properties of materials is particularly useful for manufacturing materials with precisely defined elasticity and shock absorbance.
These materials are very useful for sports goods such as sports shoes insoles.
The secret here is to combine the material with extreme performance. e.
Super hard and super strong.
Here, the unique properties offered by graphene have proved particularly useful.
Graphene can also be used to make
The material will degrade when used. Self-
Healing materials can repair damage when exposed to radiation or current, just as the living species can repair wounds or fractures.
These materials can be used to make paint for the car, which can repair scratches and restore the original shiny look.
After World War II, global plastic production soared from 15 million tons in 1964 to 0. 311 billion tons in 2014.
If everything goes on as usual, the figure is expected to double to more than 0. 6 billion tons over the next 20 years. 
It is no exaggeration to say that in the past 50 years, a plastic revolution has taken place around the world, creating trillions of dollars in world GDP.
Plastics are universal and their main use is to replace existing materials functionally.
But usually plastics are not functionally different from the materials they replace.
Creating materials that are different from what is found in nature sounds like science fiction.
Imagine that a material that is 200 times stronger and completely transparent than steel is not "better steel ";
This is a brand new thing.
Or a material, it is for reflection or refraction of light, to create color without dye, which is different from simply coloring the color you need.
These advanced materials have-
Change and expand the scope of what human beings can make.
The plastic revolution is largely driven by the discovery of organic chemistry, while the advanced material revolution is driven by the discovery of physics.
This actually means assembling new materials at the atomic and molecular levels.
In function, various technologies can be used to make advanced materials.
One way is to add the advanced material to the existing material, so that there are some properties of the advanced material in the new material.
The other is to completely create new things with an advanced material, such as a foam made entirely of graphene and air.
The third method is to design a material on a nano scale to create something of a special nature that does not exist in nature.
The key is that while great progress has been made in pure advanced material technology, there are actually thousands of products and processes that are mixed.
Adding graphene nano-flakes to polymers can change the strength, conductivity and thermal conductivity of these polymers.
Two-dimensional materials, essentially an atomic thick material, can be manufactured and then processed into structures such as film, paint or ink, which reflect some of the features of these materials.
For example, the graphene 3D laboratory has produced a 3D printed filament with graphene nano-flakes in its structure.
The result is that the 3D printing medium is many times stronger than the ordinary polymer filament.
In addition, the conductivity and thermal capacity of the polymer are improved by injecting the polymer into graphene.
Graphene 3D materials can now be purchased.
Do you want invisible clothes?
You will have to wait longer, but advanced material science is working on the technology to control the light in an extraordinary way.
In laboratory scale, it has become a reality to construct nano-scale materials that can reflect or bend light.
There are several ways to work.
Manufacturing artificial mirage by heating carbon nanotubes is a promising way.
Another way is to make materials that are smaller than the wavelength of visible light, and to construct them in a way that bends light around an object, like a rock forcing water in a stream to bypass an object.
On a more practical level, create super
Thin films using graphene or other two-dimensional materials allow technicians to teach useful properties to more traditional materials.
Graphene, for example, repels water very effectively.
Apply a film or clear paint on the glass, which means that the glass does not need to be cleaned.
Similar applications, but this time in marine coatings, will reduce corrosion and dirt, thereby reducing the efficiency of the ship.
Advanced Material Technology is creating products that are impossible to use traditional materials.
Non-dyed textiles, conductive polymers, room temperature conductors-
In thousands of applications, advanced materials show great promise in changing the way we understand what can be done.
The History of Material Science tells us that when a new material, a new set of tools, is introduced, it may take decades for its revolutionary aspects to come into full play.
The first synthetic polymer invented in 1907 was developed in 1920 and 1930s, but it was not until 1950s that various forms of "plastic" became the main industrial materials around the world.
On the one hand, the advanced materials are largely the place where the glue was in 1907 --
Technology that is gradually understood and applied.
However, unlike 1907, advanced materials technology has benefited from great advances in global R & D capabilities, science and engineering technologies, and modern computing and communication technologies.
Knowledge to promote the revolution of advanced materials spread rapidly.
New apps can find the market overnight.
Advanced materials are not for decades, but to change the world in a few years.
This means that in the near future, we can foresee that Nano and smart materials will be part of our daily lives, just like plastic in the past.
Graphene 3D laboratory has positioned its Advanced Materials Department as the forefront of the commercial of advanced materials. www. mckinsey. com/business-functions/sust. . .