ISO 17298: Biodiversity for organizations – Guidelines and Requirements, aims to provide a practical, scalable framework to help organisations assess their biodiversity impacts, dependencies, risks and opportunities.

With biodiversity under increasing pressure, ISO’s new standard offers an important tool to help organisations take measurable, accountable action to protect and restore biodiversity.

ISO hopes the new standard will empower organisations to strengthen operations, access nature-positive finance, and build trust with customers, regulators, and society – reducing regulatory and reputational risks and the disruption to supply chains and higher operating costs that can be associated with biodiversity loss.

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Phosphorus (P) is essential to human life and vital for food production. It is the critical building block of DNA, cell membrane and bones and plays a crucial role in cellular energy metabolism. Today, P is mostly obtained from mined phosphate (P_i) rock, but natural reserves of P_i rock are concentrated in a limited number of countries such as Morocco, China, and the US. On the other hand, an inefficient use of P and the leakage of phosphate-containing fertilisers, detergents and sewage into water bodies are causing irreversible eutrophication problems. Moreover, mined P_i rock is largely contaminated with toxic heavy metals such as cadmium and radioactive uranium. From health and environmental perspectives, there are increasing concerns about the long-term application of chemical fertilizer to farmland.

Increasing attention has been paid to the development of P refinery technology that can recover P from waste streams and reuse recovered P products for agricultural and industrial purposes. In the wastewater treatment sector, P is removed from wastewater using chemical or bio-based technologies. Removed P ends up in sewage sludge which is then subjected to anaerobic digestion, dewatering and incineration. This offers hot spots for P recovery from (i) the rejected water from sludge dewatering, (ii) digested sludge, (iii) and incinerated sludge ash.

More than 70 full-scale P recovery plants are currently operating in Europe, North America, and East Asia. Basically, the P recovery technologies are (i) chemical P_i leaching from incinerated sludge ash, (ii) P_i salts precipitation, and (iii) struvite crystallization after anaerobic sludge digestion. Incinerated sludge ash having the high content of P is also used as a raw material for the manufacture of phosphoric acid in a wet acid process.

P recovery practices are now expanding not only to the wastewater treatment sector but also to the manufacturing sector. In the manufacturing sector, P_i must be removed from wastewater to meet stringent effluent regulation in areas vulnerable to eutrophication. The recycling of recovered P products as a fertilizing material can save the costs of sludge disposal and leads to the significant reduction of plant operating expenses. P recovery is also practiced from solid waste streams such as animal manure and steelmaking slag. In East Asian countries, including China, Korea and Japan, steelmaking slag is one of the most important secondary P resources. Recovering P from steelmaking slag allows the rest to be reused as raw materials in blast furnaces. This has the enormous potential to improve the resource efficiency of steelmaking process.

Except some European countries such as Switzerland and Germany, no regulation requires P recover and recycling for the wastewater treatment sector. This allows the wastewater treatment sector to consider P recovery as an extra service. On the other hand, fertilizer companies cannot accept recovered P products unless they bring some economic benefits to their business. P recycling practitioners need to establish stable channels for the distribution and sale of recovered P products. To make P recycling business more attractive, it is critical to develop a new value chain that can extract the maximum value from secondary P resources.

East Asian countries are becoming increasingly the center of high-tech industries in the global economy. They need high-purity P compounds for manufacturing high-value added products including semiconductor, lithium battery, liquid crystal panel, medicine, and fire-retardant plastics. Elemental P, called white or yellow P, is the essential starting material for the manufacture of high-purity P compounds. The secured supply of elemental P is becoming increasingly difficult in the global market. Actually, the supply risk is much higher than that of P_i rock. EU added elemental P to the list of its critical raw materials, taking into account the potential risk of the secured supply of high-purity P compounds in Europe.

Elemental P is now produced by only four countries in the world, including China, USA, Kazafstan, and Vietnam. The production of elemental P is an energy-intensive process which is strongly dependent on locally-sourced electricity, P_i rock, and cheap labor forces. It requires approximately 14 MWh of electricity for each ton of elemental P produced. Moreover, since P_i rock is contaminated with toxic heavy metals and radioactive elements, pollution control is another difficult problem regarding the production of elemental P from P_i rock using a conventional arc process.

To solve these issues, it is necessary to redefine the P value chain through technology and business innovation based on recycling. The technology innovation needs to promote the development of (i) highly-efficient P recovery from secondary resources, (ii) an improved wet acid process to generate phosphoric acid from recovered P products, (iii) an innovative carbothermal reduction of low-grade P_i to elemental P with minimum electricity consumption and low environmental burden, and (iv) new processes for the manufacture of high-value added P compounds to meet the demand from high-tech industries. Among them, the key technology is the innovative carbothermal reduction of low-grade P_i to elemental P.The technology and business innovation based on P recycling, called P Innovation, can make a great contribution not only to the sustainability of agriculture but also to the secured supply of high-purity P compounds to the high-tech industry. There is no significant tradeoff in the use of P between agriculture and industry, because industry needs only a small fraction of recovered P for their business. Rather, redefining the supply chain of high-purity P compounds can offer economic incentives to P recovery from secondary P resources, thereby making a great contribution to the sustainable use of P not only in agriculture but also in industry.

Hisao Ohtake is a Guest Professor of Phosphorus Atlas Research Institute at Waseda University, Tokyo, Japan. He is also a Professor Emeritus of Osaka University, Osaka, Japan. He serves as the Chairman of Phosphorus Recycling Promotion Council of Japan, which is now being reorganized to the Phosphorus Industry Development Organization of Japan. His recent publication is Phosphorus Recovery and Recycling, Springer Nature, 2018.

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The commission is looking to develop the circular economy in its member states. Non-potable water will be harnessed and treated for farmers to use in agricultural irrigation, in a move which the commission says will not only benefit farmers but the environment as well.

“This proposal will create only winners. Our farmers will have access to a sustainable supply for irrigation water, our consumers will know the products they eat are safe, and our businesses will see new opportunities,” said Karmenu Vella, European Commissioner for Environment, Maritime Affairs and Fisheries.

“The biggest winner of them all will be our environment as the proposal contributes to better management of our most precious resource–water.”

The proposals from the commission include minimum requirements for the reuse of treated wastewater, ensuring its safety in irrigation. Further risk management is proposed to address any other potential water safety risks.

Greater public involvement is also needed. The commission recommends citizens of member states be given access to information on the practice of water reuse, helping to act as an educational tool for European citizens, many of whom could be directly affected by the overuse of freshwater resources.

The commission says that current levels of water reuse are not good enough, and that increasingly unstable weather patterns in the context of climate change have heightened the need to urgently protect water resources.

The proposal completes the existing EU legal framework on water and foodstuffs, forming part of the Commission’s 2018 Work Programme. A key aim of transitioning to a circular economy constitutes a cornerstone of these proposals, and it is hoped this will lead to a reduction of total EU land suffering from water stress–currently standing at one third.

The measures will also assist the EU come closer to completing the UN’s Sustainable Development Goal Six, on water and sanitation.

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