Other applications

Sensing Applications: Advanced Materials for Precise Detection Solutions

At Gnanomat, we are transforming the field of sensing by developing cutting-edge materials that are tailored to meet the most demanding detection needs. Through our hybrid technology, we have engineered advanced materials that offer exceptional sensitivity, scalability, and customization, making them ideal for gas sensing applications.

Our materials have been rigorously tested and proven to be effective in a range of sensing environments. As highlighted in recent studies published in MDPI (Gas Sensing with Advanced Materials and Functional Inks for Sensing Applications), Gnanomat’s technology offers significant advantages in gas detection, with our materials providing a high degree of sensitivity, selectivity, and stability over time. These attributes are crucial for applications in areas like environmental monitoring, industrial safety, and healthcare, where precise and reliable detection is essential

One of the key innovations at Gnanomat is our ability to scale up the production of these advanced materials. We can efficiently modify and customize our materials to meet the specific needs of different applications, offering flexibility and versatility for developers and manufacturers. This capability not only ensures high performance but also makes our materials easily adaptable for large-scale production, delivering cost-effective solutions without compromising quality.

Additionally, our expertise in functional inks is a game-changer for sensing technology. Gnanomat’s functional inks can be used to print sensors onto various substrates, offering a simple, scalable, and low-cost approach to developing gas sensors. These inks can be easily integrated into flexible, lightweight devices, which are ideal for wearable technology, portable sensors, and other innovative applications. This makes the deployment of cutting-edge sensing solutions both efficient and scalable.

With Gnanomat’s advanced materials and functional inks, we are pushing the boundaries of gas sensing technology, enabling the creation of sensors that are more sensitive, durable, and cost-effective. As we continue to refine and expand our material capabilities, we are excited to offer tangible, scalable solutions for the next generation of detection systems across diverse industries.

EMI Shielding and RAM Applications

With the growing demand for electronics in complex electromagnetic environments, Gnanomat’s materials excel in providing superior EMI shielding. These materials offer advanced protection against disruptive electromagnetic signals, making them ideal for industries ranging from consumer electronics to defense systems. Their hybrid technology enables extraordinary shielding performance, crucial for both everyday devices and high-end applications like military systems.

Aerospace and Defense Applications

In aerospace and defense, the need for high-performance materials that can withstand extreme conditions and offer advanced electromagnetic properties is vital. Gnanomat’s materials are highly adaptable, offering tailored solutions in ferromagnetic, superparamagnetic, and other advanced forms. These materials are perfect for applications like radar systems, electronic warfare, and stealth technologies. Gnanomat’s unique capabilities in electromagnetic shielding and radar absorption make them essential for next-generation defense systems.

Automotive and Electronics

The automotive industry, particularly with the rise of electric vehicles (EVs) and advanced driver-assistance systems (ADAS), benefits from Gnanomat’s EMI shielding materials, ensuring the reliability and safety of automotive electronics. Additionally, in consumer electronics, our materials protect devices from electromagnetic interference, ensuring seamless operation across a wide range of products.

Key Collaborations

Gnanomat partners with top industry leaders to drive the scaling and innovation of these materials for defense, aerospace, automotive, and electronics. These collaborations foster breakthroughs in EMI shielding and RAM technologies, enabling us to meet the stringent requirements of various sectors.

Gnanomat’s soft magnetic materials offer a powerful solution to the challenges of EMI shielding, pushing the boundaries of material science across multiple industries.

Biocide Properties of Gnanomat’s Materials

Gnanomat’s materials offer exceptional biocide properties, including strong antiviral and antimicrobial activity. These materials have shown significant effectiveness in inhibiting viral infections, particularly against SARS-CoV-2, the virus responsible for COVID-19. Testing reveals that Gnanomat’s materials disrupt the viral structure, preventing infection and offering a promising solution for reducing virus spread in high-risk environments.

In addition to antiviral properties, Gnanomat’s materials exhibit powerful antimicrobial activity, inhibiting the growth of bacteria and fungi. This makes them ideal for use in hygiene-critical applications, reducing microbial contamination on various surfaces.

These biocidal materials can be applied to a wide range of substrates, including ceramics, natural stone, air filters and textiles, providing long-lasting protection. They are especially beneficial in healthcare, public spaces, food processing, and consumer goods, where cleanliness and pathogen control are paramount.

Gnanomat’s antiviral and antimicrobial materials offer a science-backed solution to enhance safety and hygiene across multiple industries, playing a key role in reducing the transmission of harmful pathogens.

Internally, the biocidal effect of a surface coated with Gnanomat anti-microbial additive was evaluated against pathogens from bacteria sources (gram positive and negative models) and a viral model (Escherichia coli, Staphylococcus aureus and bacteriophage MS2) following the BS EN ISO22196 testing protocol. In these tests the biocide effect was also observed either with long (24 hours of pathogen exposure to treated surface) and short (1 hour of exposure) with a reduction of up to three levels of magnitude (99.9% pathogen inactivation). (Texto cogido de  “Production and application of hybrid nanomaterials”)