Prospective analysis of the flows of certain rare earths in Europe at the 2020 horizon.

This paper proposes a forecast of certain rare earth flows in Europe at the 2020 horizon, based on an analysis of trends influencing various actors of the rare earth industry along the value chain. While 2020 is indicated as the forecast horizon, the analysis should be considered as more representative of the next decade. The rare earths considered here are used in applications that are important for a low-carbon energy transition and/or have a significant recycling potential: NdFeB magnets (Pr, Nd, Dy), NiMH batteries (Pr, Nd) and fluorescent lamp phosphors (Eu, Tb, Y). An analysis of major trends affecting the rare earth industry in Europe along the value chain (including extraction, separation, fabrication, manufacture, use and recycling), helps to build a scenario for a material flow analysis of these rare earths in Europe. The scenario assumes in particular that during the next decade, there exists a rare earth mine in production in Europe (with Norra Kärr in Sweden as a most likely candidate) and also that recycling is in line with targets proposed in recent European legislation. Results are presented in the form of Sankey diagrams which help visualize the various flows for the three applications. For example, calculations forecast flows from extraction to separation of Pr, Nd and Dy for magnet applications in Europe, on the order of 310 tons, 980 tons and 80 tons rare earth metal resp., while recycled flows are 35 tons, 110 tons and 30 tons resp. Calculations illustrate how the relative contribution of recycling to supply strongly depends on the situation with respect to demand. Considering the balance between supply and demand, it is not anticipated any significant shortage of rare earth supply in Europe at the 2020 horizon, barring any new geopolitical crisis involving China. For some heavy rare earths, supply will in fact largely outweigh demand, as for example Europium due to the phasing out of fluorescent lights by LEDs.

[1]  R. Kleijn,et al.  Recycling as a strategy against rare earth element criticality: a systemic evaluation of the potential yield of NdFeB magnet recycling. , 2013, Environmental science & technology.

[2]  Luis A. Tercero Espinoza,et al.  Can a dysprosium shortage threaten green energy technologies , 2013 .

[3]  Perrine Chancerel,et al.  Recycling-oriented characterization of small waste electrical and electronic equipment. , 2009, Waste management.

[4]  Basudev Swain,et al.  Materials flow analysis of neodymium, status of rare earth metal in the Republic of Korea. , 2015, Waste management.

[5]  ThE CirCUlAr,et al.  EU Action Plan for the Circular Economy , 2016 .

[6]  Tzimas Evangelos,et al.  Critical Metals in the Path towards the Decarbonisation of the EU Energy Sector: Assessing Rare Metalsas Supply-Chain Bottlenecks in Low-Carbon Energy Technologies , 2013 .

[7]  Saumitra Das,et al.  Interplay between NS3 protease and human La protein regulates translation-replication switch of Hepatitis C virus , 2011, Scientific reports.

[8]  D. Dubois,et al.  Material flow analysis applied to rare earth elements in Europe , 2015 .

[9]  Stephen B. Castor,et al.  RARE EARTH ELEMENTS , 2006 .

[10]  T. Graedel,et al.  Uncovering the Global Life Cycles of the Rare Earth Elements , 2011, Scientific reports.

[11]  Richard Roth,et al.  Evaluating rare earth element availability: a case with revolutionary demand from clean technologies. , 2012, Environmental science & technology.

[12]  Helmut Rechberger,et al.  Practical handbook of material flow analysis , 2003 .

[13]  Dominique Guyonnet,et al.  A fuzzy constraint-based approach to data reconciliation in material flow analysis , 2014, Int. J. Gen. Syst..

[14]  Henrik Wenzel,et al.  Exploring rare earths supply constraints for the emerging clean energy technologies and the role of recycling , 2014 .

[15]  Karen Smith Stegen Heavy rare earths, permanent magnets, and renewable energies: An imminent crisis , 2015 .

[16]  R. Rudnick,et al.  Composition of the Continental Crust , 2014 .

[17]  T. Graedel,et al.  Global in-use stocks of the rare Earth elements: a first estimate. , 2011, Environmental science & technology.

[18]  Simon Warren,et al.  Methodology of metal criticality determination. , 2012, Environmental science & technology.

[19]  T. Graedel,et al.  Global Rare Earth In‐Use Stocks in NdFeB Permanent Magnets , 2011 .

[20]  T. Graedel,et al.  Dysprosium, the balance problem, and wind power technology , 2014 .

[21]  I. Pulford Waste Electrical and Electronic Equipment (WEEE) , 2013 .

[22]  Tom Van Gerven,et al.  Recycling of rare earths: a critical review , 2013 .

[23]  I. R. Harris,et al.  Optimisation of the processing of Nd–Fe–B with dysprosium addition , 2010 .

[24]  Vera Susanne Rotter,et al.  Data availability and the need for research to localize, quantify and recycle critical metals in information technology, telecommunication and consumer equipment , 2013, Waste management & research : the journal of the International Solid Wastes and Public Cleansing Association, ISWA.

[25]  Patrice Christmann,et al.  STRENGTHENING THE EUROPEAN RARE EARTHS SUPPLY-CHAIN Challenges and policy options A REPORT BY THE EUROPEAN RARE EARTHS COMPETENCY NETWORK (ERECON) , 2015 .