The ambitious future of India’s rail infrastructure requires prudent investments that ensure its long-term viability. This is where nickel-containing steels play a vital role.
Nickel-based catalysts are key to supplying energy to power our transportation of goods and people, whether by land, sea, or air.
Mark Mistry and Marco Vallini argue that for the EU Critical Raw Materials Act to fulfil its promise to address the energy transition, industry needs planning security for both ‘critical’ and ‘strategic’ raw materials.
The sudden failure of a building or bridge is mercifully a rare event, thanks largely to international or national standards: structures are designed in accordance with a design standard, using products conforming to a product standard and manufactured using techniques and to a quality level defined in a construction standard.
The proposed Regulation will introduce a wide range of sustainability requirements and promote the recycling of key battery raw materials like nickel. EU legislative work is entering a crucial phase.
Nickel-based alloys and nickel-containing stainless are playing key roles in an emerging source of renewable energy known as thermal solar plants or concentrated solar power (CSP). Their use has enabled the industry to overcome challenges in heat transfer and thermal storage technology.
If you’re like me and predictive text has led to some awkward if not amusing moments, you might be sceptical about Artificial Intelligence (AI). But its achievements are already overwhelming and changing, even protecting, our lives in many sectors.
Around two-thirds of today’s buildings will still be around in 2050, and by 2060, the world is projected to add 230 billion m² of buildings - an area equivalent to the entire current global building stock. What can the building and construction sector do to reduce the environmental burden of buildings?
Nickel’s role in enabling technologies is not always common knowledge. Yet its versatile properties present great opportunity for the nickel industry.