The strongest material known to mankind was first discovered with sticky tape. Today, this two-dimensional (2-D) version of carbon known as graphene is the subject of intense research around the world. Many hope its unique properties could lead to breakthroughs in fields from electronics to medicine.

By 2-D we mean it is made from a single layer of atoms. In graphene's case, these are arranged in a hexagonal pattern that help make it incredibly strong. It also conducts electricity and heat at unprecedented levels, is impermeable to gases and can be both brittle and ductile.

Yet while graphene has received incredible attention and won its discoverers a Nobel Prize, it's no longer alone in the world of 2-D materials. Many other similar materials have since been predicted and isolated, each with similar structural properties to graphene but also a variety of unique individual characteristics.

In fact, there are so many 2-D materials with such a wide variety of properties that we can effectively use them to design and build new 3-D materials with the exact characteristics we want. This idea of an atomic-scale "Lego set" creates potentially infinite possibilities for new substances.

Theoretically, almost any 3-D material can have a 2-D counterpart. The list so far includes: silicene (a single layer of silicon), phosphorene (a single layer of black phosphorus), and various monolayers of chemical compounds known as transition-metal dichalcogenides (TMDCs), such as molybdenum disulfide (MoSâ‚‚) and molybdenum ditelluride (MoTeâ‚‚). Research is ongoing into probably dozens of methods to isolate these materials. The two main methods used are mechanical exfoliation – which was the method first used to make graphene by isolating individual layers with adhesive tape – and by effectively growing a 2-D layer of crystals directly onto a flat base.

In practice, however, there are many limitations to what is currently possible. Only highly thermally and chemically stable materials can be separated into monolayers, which immediately discounts many elements. And, once isolated, many metallic monolayers in particular tend to corrode or oxidise in a way that destroys their desired properties.

Once you have a 2-D material, you can then layer it with other substances of very different chemical properties to create "heterostructures". For instance we can combine semiconductors with magnets, or metals with superconductors. The list of possible combinations grows exponentially.

These can be tailored with atomic precision using scanning tunnelling microscopes. These methods involve generating an electric current between a surface and the tip of the atomically fine probe to pick up and move individual atoms. One such 2-D heterostructure that has been made in the lab combines atomic monolayers of graphene and hexagonal boron nitride (h-BN).

Completely new functionalities

Both 2-D materials and heterostructures have already found many actual and potential applications across a broad range of areas. For example, graphene has made possible the dream of "printing" circuits onto flexible plastic bases, at least in a lab. In the future, this could lead to consumer products such as flexible TVs, smartphones and more user-friendly wearable devices.

The discovery of a multitude of other 2-D materials has opened up almost infinite ways of combining different properties, which could hugely improve or speed up the development of these applications. For example, using h-BN as the base for graphene electronics instead of the traditional silicon dioxide could mitigate some of the problems with the technology. Because h-BN monolayers are ultra-flat and can be isolated in the same way as graphene, it's possible to remove atomic flaws in the base that interfere with the properties of the graphene sheet.

Furthermore, advancements in 2-D materials research is enabling a new way of making computer processors even faster; something which is seen as vital to maintaining the progress of electronic technology. Computer chips make their calculations using large numbers of transistors, each of which works by moving electrons between different layers of semiconductor material. Having more than one type of 2-D material means you can use them to make each of the different semiconductor layers just one atom thick. As transistors become smaller, more of them can be placed onto each computer chip, and this then naturally leads to the production of faster processors.

We could also see graphene and other 2-D materials used to help generate and store energy. For example, graphene-based heterostructures can be used to help create highly efficient and flexible solar and fuel cells. These heterostructures are also being used to develop next-generation batteries and supercapacitors, which promise faster charging and extended energy output. Scientists have even managed to create 2-D versions of materials that had previously been though impossible, such as a 2-D version of the mineral perovskite, which could be used to improve LEDs.

With the growth of electric cars and companies such as Tesla leading us towards a future of greener energy conversion and storage solutions, there is sure to be a huge focus on this sort of technology for the foreseeable future.