How to make a functional material that is modular in nature

The concept of modularity in materials is a controversial topic in materials science, as the properties of a material are dependent on how it’s used.

There are a lot of theories on the topic, but the general rule is that materials that have a very high degree of structural and mechanical flexibility should have high stiffness and/or high stiffness to weight ratios, while materials with a low degree of flexibility should be stiffer and/of heavier weight.

In this article, we will look at a material called the polymer-coated glass.

The polymer coating is formed by a combination of polymer particles, which are bound together by an adhesive, and glass particles, that are chemically bonded to the adhesive.

As the polymer coating forms, the glass particles become more and more attached to the polymer.

When they get too much attached to one another, the polymer molecules get released and the material breaks apart, forming a new, more rigid polymer.

The polymer coating process is not unique to glass.

Many materials have their own polymer-casing processes that are used to form the polymer layers.

However, these polymer layers are typically made of very fine particles that have the same mechanical properties as the polymer layer.

This makes it easy to make small, relatively large-sized polymer layers, which is useful for many applications, such as in solar cells, ceramics, and some metals.

In order to make the polymer coated glass, you need a material that has been made from glass.

However the process of making glass is very simple.

You need a solution of glass-containing materials, such like silica, silicate, or aluminum, that is very soluble in water.

When dissolved in water, the water can bind the silica and silicate molecules together, creating a polymer.

Once the polymer is formed, you can dissolve the silicate into water, and the silicic acid can dissolve in the solution, forming an acidic solution.

This process is used to produce polymer layers that have both high tensile strength and high stiffness.

Once the polymer has formed, the first step is to heat the solution to at least 500°C.

This heats the solution in a way that it will react with the polymer and create a polymer coating.

When the polymer begins to bond with the silicates, it will start forming a bond with these silicate-containing silica-containing polymer layers and start to bond to the silicas.

These bonds are called thermal bonds.

This is because the bond is formed with the melting point of the silics.

Once this bond has formed between the siliceous layers, the temperature is now high enough to break up the polymer, creating another polymer layer and forming a final coating.

The glass coating is then dissolved into water and the polymer slowly melts in water as the process progresses.

This will leave behind a very small amount of polymer.

As a result, the final polymer layer is a very light and flexible polymer layer that has very high tensility and a very low strength to weight ratio.

As it melts, the strength to material ratio of the polymer will increase as the temperature rises, but this process is relatively slow.

The final polymer is much more brittle than the polymer that formed before.

This means that the polymer becomes brittle at temperatures below about 5,000°C and above about 30,000 °C, depending on the strength of the bond.

In the process, the siliques are bonded to other polymer-containing layers, and they can also be bonded to each other.

When this is done, the resulting polymer layer has the ability to act as a self-heating structure.

This allows for the polymer to become super-stiff at higher temperatures, because the polymer itself can’t expand much.

This also means that even when the polymer melts, it doesn’t have much energy left, as it will not expand very much.

However this also means the polymer can still be used to create super-strength, high-stability, and low-tensile properties in applications where it is used as the super-heated, rigid, and highly tensile part of the structure.

The properties of the glass polymer are very versatile.

The coating can be applied to various kinds of materials, and many of these materials have properties that are not found in the materials that are actually made from the material.

For example, glass is used in a wide range of materials that can’t be made from a material made from any other material.

However there are many applications where glass is a useful material, such a ceramic, glass, and ceramically treated materials.

The material is also very easy to form, and can be used in the production of glass parts.

The glass polymer coating also works well as a catalyst for the synthesis of polymer chains.

This may not sound like a huge deal, but it makes the material very versatile in the fabrication of parts.