One sensed at last year’s PGMs Industry Day that Nornickel’s Palladium Center would be back this year with many more growth opportunities for South Africa’s platinum group metals (PGMs).

That expectation turned out to be spot-on when Dmitry Izotov, the director of Nornickel’s Palladium Center, outlined the three-year-old centre’s long list of advancing new palladium applications at this year’s high-spirited PGMs Industry Day, where PGM-linked hydrogen expectations also resurfaced, amid Northam Platinum’s first-hand witnessing of hydrogen fuel cell mobility on an information-gathering visit to China.

Speaking during a panel discussion on quantifying PGMs demand in non-automotive applications, Izotov focused on three potential major long-term growth areas where the Palladium Center is concentrating development efforts.

The first of these is a focus on solar power, which was hailed as “the main alternative source of energy, the future source of energy”.

Putting forward his contentions that current silicon solar cells have reached a maximum efficiency of around 30% and describing their thickness as rendering them relatively costly to produce, Izotov reported a transitioning to tandem PV panels that combine silicon with perovskite materials. “The perovskite has a wider fill factor, so it can better catch the light during sunset and sunrise,” Izotov reported. On that basis, PV panels that combine silicon with perovskite materials uplift efficiency and cuts costs because of their thinness.

Of the two types of palladium-based products being developed for the solar sector, the first is an additive to the perovskite active layer that has already demonstrated a 15% efficiency boost during testing, and the second is a tandem cell configuration with three palladium layers designed to address lifespan issues by leveraging palladium’s proven barrier function characteristics for microelectronics applications.

“We really think it’s a big opportunity for palladium, because currently in China the largest solar panel producers don’t have this technology ready. By the end of the year, we’ll have the first prototype and we expect to distribute these technologies to the big Chinese market,” the Palladium Center CEO explained.

The centre’s projected new demand for solar-linked palladium is 0.5-million to one-million ounces a year from around 2030 to 2035.

Microelectronics

Microelectronics, where gold dominates with nine-million ounces of annual demand, was highlighted as a second potential major long-term growth area. “It’s nine-million ounces, so it’s like palladium’s total demand. For our PGM metals, it’s a huge opportunity and a huge market,” Izotov enthused.

With data centres for AI driving demand for next-generation printed circuit boards and high gold prices creating cost pressures, two product streams are being developed, one being new gold-palladium layer combinations that reduce gold content while increasing palladium, and the other using palladium-copper bonding wires to replace gold-based applications.

While there is room for more gold reduction, gold will remain a perfect metal in terms of electroconductivity and corrosion resistance, but in smaller volumes.

The projected new demand for microelectronics-linked palladium is for at least one- million ounces a year, again from around the years 2030 to 2035.

Lithium-Sulphur Batteries

The third potential major long-term growth area is in lithium-sulphur battery technology, which the Palladium Center sees as offering advantages over lithium-ion batteries in several fields of application owing to lithium sulphur being cheaper, lighter and a higher density than lithium-ion. The shorter lifespan of lithium-sulphur batteries is being dealt with by palladium-based catalysts for both electrolyte and cathode to neutralise sulphur’s side effects.

The projected new palladium demand for lithium-ion batteries is expected to be a minimum of 1.5-million ounces a year after market entry.

AI-Driven Materials Development

In focusing on generative AI for materials discovery, parallels to pharmaceutical breakthroughs have been drawn in that the creation of AlphaFold to predict proteins’ three-dimensional structure has expanded the protein database from 190 000 to 200-million entries.

Nornickel is developing a proprietary AI platform for predicting properties of PGM non-organic materials and alloys, based on a vast dataset of test results and industrial information.

Models based on AI can significantly streamline the search for palladium–carbon nanotube composites by predicting their electroconductivity and interface stability, as well as the optimal form, position and size at which carbon nanotubes should be distributed within the palladium crystal structure. The resulting composite will have better conductivity, which positions palladium as a viable replacement for the nine-million ounces of gold consumed annually in the microelectronics industry.

Beyond Auto Dominance

The Palladium Center was established in 2023 in response to automotive electrification trends. “We understood that we needed to launch some massive market development programme to support palladium in new industrial applications,” Izotov recalled, “because we understood that platinum was already pretty diversified, but for palladium the biggest share of the market was always autocatalysts.”

The centre, as reported last year by this publication, set a target to create 1.7-million ounces of new annual palladium demand by launching 15 new projects annually for commercially viable palladium-based materials. This has been achieved in that 30 projects spanning various application areas are now active.

Glass Industry

The glass industry represents the most advanced market development effort. Currently, eight-million ounces of primarily platinum and rhodium are used in fiberglass, optical, technical, and display glass production.

Developed are palladium-platinum alloys strengthened with special additives to address palladium’s lower melting point and reduced stability at the high temperatures required for glass production (1 300 °C for fiberglass).

Commercial traction is accelerating. In 2025, Chinese companies purchased 20 000 oz of palladium for the first installation phase of fiberglass production leads. Three hundred days of industrial testing at one of China’s largest production facilities proved successful, and the industry is now transitioning to palladium-based leads.

Major industrial testing of the main palladium-platinum alloys for bushings, which is scheduled to begin next month, will continue throughout the year.

Projected demand is 0.8-million ounces from adoption of fiberglass bushings in China and up to two-million ounces is the total potential across fiberglass, optical, technical, and display glass.

The fast adoption cycle is aided by fiberglass equipment’s one-year lifespan, enabling rapid switching compared with some oil and chemical catalysts that have eight-year lifecycles.

Electrochemistry

The three-component palladium-iridium- ruthenium anodes that have been developed reduce scarce iridium content, which renders the anodes 15% cheaper and 20% more energy efficient than conventional iridium-ruthenium anodes, with applications spanning cathode nickel production, copper foil manufacturing, water disinfection, and chloralkali processes.

Commercial installations of palladium- based anodes for water disinfection are already operating in water treatment plants, with development work continuing on the remaining applications.

Projected new mid-term palladium demand from electrochemistry is from 0.2-million to 0.3-million ounces.

Development Approach

Nornickel’s hybrid research and development model involves partnering with external scientific groups for each specific project, while fundamental palladium competencies are maintained through a palladium laboratory, which uses AI-enhanced capabilities for developing catalysts, alloys, and functional materials.

This approach has accelerated time-to- market significantly, with lab prototypes being made in nine months compared with 18 to 24 months. The electrochemistry water disinfection project moved from concept to 500 installed anodes in 14 months, compared a typical five to ten years.