Graphene, with its extensive two-dimensional structure composed of a single layer of carbon atoms, provides it with the ability for self-cooling and extensive interaction sites. In other words, it is sensitive to any molecules deposited on its surface and can react with other substances to form compounds with new or improved properties.

Despite its hardness and rigidity, graphene is a flexible and elastic material, allowing for reversible elongation and the ability to bend without suffering any damage. Therefore, materials containing graphene are less likely to break and are more durable.

Unlike many materials that deteriorate or degrade due to the effects of UV radiation, graphene maintains its structural integrity and mechanical properties. This makes it a promising candidate for applications that require long-lasting protection against sunlight, such as protective coatings, plastics, textiles, construction materials, and outdoor electronic devices. It can also be used in environments where radiation is emitted (hospitals) to create safer health zones and reduce the degradation of exposed materials.

If any of the graphene layers lose atoms, neighboring atoms interact to fill the gaps, restoring their connections. This process allows graphene to maintain its structure and properties despite encountering deformations and damage.

In its purest form, graphene is a highly efficient electrical conductor with conductivity even 10 times greater than copper or aluminum. Under certain conditions, it can also act as a semiconductor. Additionally, its self-cooling capability allows it to withstand intense electrical currents without heating up.

The arrangement and electronic density of both graphene and GO sheets creates a sinuous and repulsive path against the adhesion and growth of microorganisms from their surface to the interior of their structure. Furthermore, its biocompatibility has allowed it to enter the medical field mainly for tissue engineering in bone and skin regeneration or for the design of joint prostheses or dental materials for the design of materials with longer useful life thanks to greater mechanical resistance, better cellular stimulation and lower risk of infection.

The combination of biocompatibility and antimicrobial activity makes GO a versatile and promising material in the search for innovative solutions to improve people’s health and quality of life.

The hardness of Graphene is greater than that of diamond and approximately 100 times stronger than steel at the same thickness. It is also rigid, capable of withstanding significant forces without deforming. This makes graphene ideal for applications in areas that require high strength and durability.

Graphene is an excellent thermal conductor because electrons move freely and at high speed across its entire surface. This characteristic has made it a highly studied and applied material for the design of electronic devices, cooling systems, and other technologies that generate heat during their operation. Graphene is used not only to dissipate heat but also to optimize the performance of such systems.

The arrangement and electronic density of graphene layers create a winding path that repels the adhesion and growth of microorganisms from its surface into its structure. Furthermore, its biocompatibility has allowed it to make advances in the medical field, mainly in tissue engineering for bone and skin regeneration, designing joint prostheses, or dental materials, resulting in longer-lasting materials with improved mechanical strength, enhanced cellular stimulation, and a reduced risk of infection.

The combination of biocompatibility and antimicrobial activity makes graphene a versatile and promising material in the quest for innovative solutions to improve people’s health and quality of life.