Zinc (30)

solid, primordial, metal, transition metal

    Name: Zinc
    Atomic number: 30
    Symbol: Zn
    Origin of name: the German Zink
    Period: 4
    Group: 12
    Atomic weight: 65.38 u
    Density: 7.13400000 g/cm3
    Melting point: 692.88 °K
    Boiling point: 1180 °K
    Specific heat capacity: 0.388 J/(g*K)
    Electronegativity: 1.6 (χ)
    Abundance in Earth's crust: 70 mg/kg
    State: solid
    Natural occurrence: primordial
    Metallic classification: metal
    Serie: transition metal

    Data from Wikipedia's "List of chemical elements" (June 2017).

    Criticality status: candidate
    Supply concentration:
    • 1.762 (moderate) *
    Supply risk: 0.3 *
    Weighted country risk: 0.09 (moderate) *
    Economic importance: 4.5 *
    Primary production:
    • China (35%) *
    • Australia (12%) *
    • Peru (10%) *
    Main product: main product *
    Co-product: -
    By-product: -
    World reserves:
    • 200,000,000 t *
    • 220,000,000 t *
    Price development:
    • price is decreasing *
    Market development:
    • market seems to be stabilized no major changes in either direction are expected *
    Conflict mineral: no
    Recycling:
    • in 2015, approximately 37% (65,000 t) of produced zinc in the USA was recovered from secondary material *
    • secondary materials: galvanizing residues and crude zinc oxide recovered from electric arc furnace dust *
    EOL recycling input rate: 31% *
    Applications general:
    • pressure die castings *
    • pigments *
    • zinc alloys *
    • metal final products *
    • electrical equipment *
    Applications Automotive: -
    Applications ICT: -
    Comments: -

    Hover over the * to get information about the references of the data.
    Hover over the under-dashed words to get further information.

    BGR (2014a) Zinn - Rohstoffwirtschaftliche Steckbriefe
    http://www.deutsche-rohstoffagentur.de/DE/Themen/Min_rohstoffe/Downloads/rohstoffsteckbrief_sn2014.pdf?__blob=publicationFile&v=4
    accessed: Ferbuary 23rd 2016
    Cullbrand & Magnusson (2012) Cullbrand, K. & Magnusson, O. (2012).
    The Use of Potentially Critical Materials in Passenger Cars.
    Master Thesis., Chalmers University of Technology: Department of Environmental Systems Analysis. Gothenburg.
    http://publications.lib.chalmers.se/records/fulltext/162842.pdf
    DERA (2013) Ursachen von Preispeaks, -einbrüchen, -und trends bei minerlaischen Rohstoffen
    http://www.deutsche-rohstoffagentur.de/DE/Gemeinsames/Produkte/Downloads/DERA_Rohstoffinformationen/rohstoffinformationen-17.pdf?__blob=publicationFile&v=2
    accessed: November 5th 2015
    DERA (2014) Angebotskonzentration bei minealischen Rohstoffen und Zwischenprodukten - potenzielle Preis- und Länderrisiken
    http://www.deutsche-rohstoffagentur.de/DE/Gemeinsames/Produkte/Downloads/DERA_Rohstoffinformationen/rohstoffinformationen-24.pdf?__blob=publicationFile&v=4
    accesssed: Nevember 24th 2015
    DERA (2016) DERA Rohstoffinformation - Rohstoffe für Zukunftstechnologien 2016.
    http://www.isi.fraunhofer.de/isi-wAssets/docs/n/de/publikationen/Studie_Zukunftstechnologien-2016.pdf#page=3&zoom=auto,-82,648
    Elsner et al. (2010) Commodity Top News Nr. 33
    Elektronikmetalle - zukünftig steigender Bedarf bei unzureichender Versorgungslage?
    http://www.deutsche-rohstoffagentur.de/DE/Gemeinsames/Produkte/Downloads/Commodity_Top_News/Rohstoffwirtschaft/33_elektronikmetalle.pdf?__blob=publicationFile&v=3
    accessed: February 22nd 2016
    European Commission (2014a) Report on Critical Raw Materials for the EU
    http://ec.europa.eu/growth/sectors/raw-materials/specific-interest/critical/index_en.htm
    accessed: November 5th 2015
    European Commission (2014b) Critical Material Profiles
    http://ec.europa.eu/growth/sectors/raw-materials/specific-interest/critical/index_en.htm
    accessed: November 5th 2015
    European Commission (2014c) Non- Critical Material Profiles
    http://ec.europa.eu/DocsRoom/documents/7422/attachments/1/translations/en/renditions/native
    accessed: February 9th 2016
    European Commission (2017) Study on the review of the list of critical raw materials
    https://publications.europa.eu/en/publication-detail/-/publication/08fdab5f-9766-11e7-b92d-01aa75ed71a1/language-en
    accessed: Octobre 11th 2017
    European Commission (2017a) COMMUNICATION FROM THE COMMISSION TO THE EUROPEAN PARLIAMENT, THE COUNCIL, THE EUROPEAN ECONOMIC AND SOCIAL COMMITTEE AND THE COMMITTEE OF THE REGIONS on the 2017 list of Critical Raw Materials for the EU
    http://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:52017DC0490&from=EN
    accessed: Octobre 16th 2017
    European Commission (2017b) Study on the review of the list of critical raw materials: Non-critical raw materials factsheets
    https://publications.europa.eu/en/publication-detail/-/publication/6f1e28a7-98fb-11e7-b92d-01aa75ed71a1/language-en
    accessed: Octobre 20th 2017
    European Commission (2017c) Study on the review of the list of critical raw materials: Critical raw materials factsheets
    https://publications.europa.eu/en/publication-detail/-/publication/7345e3e8-98fc-11e7-b92d-01aa75ed71a1/language-en
    accessed: Octobre 20th 2017
    Gunn, G. (2014) Critical metals handbook
    John Wiley & Sons, West Sussex, UK.
    NewInnoNet (2016) The Near-Zero European Waste Innovation Network
    The project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement no 642231
    http://www.newinnonet.eu/
    ORKAM (2017) Optimierung der Separation von Bauteilen und Materialien aus Altfahrzeugen zur Rückgewinnung kritischer Metalle (ORKAM) Endbericht
    Umweltbundesamt
    https://www.umweltbundesamt.de/publikationen/optimierung-der-separation-von-bauteilen
    ReStra (2017) Recyclingpotenzial strategischer Metalle (ReStra)
    Umweltbundesamt
    https://www.umweltbundesamt.de/publikationen/recyclingpotenzial-strategischer-metalle-restra
    Sander, K. et al. (2015) Sander, K.; Kohlmeier, R.; Rödig, L.; Wagner, L.;
    Altfahrzeuge - Verwertungsquoten 2015 und Hochwertigkeit der Verwertung, Conference Proceedings Recycling 2015, VIVIS Verlag, Berlin
    available online: http://www.vivis.de/kostenfreie-artikel/category/129-autos#
    UNEP (2009) Critical Metals for Future Sustainable Technologiesw and their Receycling Potential.
    Buchert, Matthias; Schüler, Doris; Bleher, Daniel
    UNEP (2013) Metal Recycling: Opportunities, Limits, Infrastructure, A Report of the Working Group on the Global Metal Flows to the International Resource Panel.
    Reuter, M. A.; Hudson, C.; van Schaik, A.; Heiskanen, K.; Meskers, C.; Hagelüken, C.
    USGS (2016) Mineral commodity summaries 2016
    http://minerals.usgs.gov/minerals/pubs/mcs/2016/mcs2016.pdf
    accessed: February 10th 2016
    USGS (2017) Mineral commodity summaries 2017
    http://minerals.usgs.gov/minerals/pubs/mcs/2016/mcs2017.pdf
    accessed: February 13th 2016
    Widmer, R. et al. (2015) Widmer, R., Du, X., Haag, O., Restrepo, E., Wäger, P.A. (2015).
    Scarce Metals in Conventional Passenger Vehicles and End-of-Life Vehicle Shredder Output.
    Environmental Science & Technology 49, 4591-4599.
    CIGS A copper indium gallium selenide solar cell (or CIGS cell, sometimes CI(G)S or CIS cell) is a thin-film solar cell used to convert sunlight into electric power. It is manufactured by depositing a thin layer of copper, indium, gallium and selenide on glass or plastic backing, along with electrodes on the front and back to collect current. Because the material has a high absorption coefficient and strongly absorbs sunlight, a much thinner film is required than of other semiconductor materials.

    CIGS is one of three mainstream thin-film PV technologies, the other two being cadmium telluride and amorphous silicon. Like these materials, CIGS layers are thin enough to be flexible, allowing them to be deposited on flexible substrates. However, as all of these technologies normally use high-temperature deposition techniques, the best performance normally comes from cells deposited on glass, even though advances in low-temperature deposition of CIGS cells have erased much of this performance difference. CIGS outperforms polysilicon at the cell level, however its module efficiency is still lower, due to a less mature upscaling.
    (Source: https://en.wikipedia.org/wiki/Copper_indium_gallium_selenide_solar_cells)
    GLR This is a German Unit made by DERA (Deutsche Rohstoffagentur).

    The weighted Country risk (GLR) is based on data from Mining, Mineral Processing and net Imports correlated with country indices or country rankings in relation to the World-wide Governance Indicators of the world bank (Worldbank 2014). The country indicators are based on :
    • Voice and Accountability
    • Political Stability and Absence of Violence
    • Government Effectiveness
    • Regulatory Quality
    • Rule of Law
    • Control of Corruption
    Details are available in German in the DERA report „DERA Rohstoffinformationen 2014“ on page 13:
    https://www.bgr.bund.de/DE/Gemeinsames/Produkte/Downloads/DERA_Rohstoffinformationen/rohstoffinformationen-24.pdf?__blob=publicationFile&v=4

    The DERA has also the newest publication for the raw materials:
    https://www.deutsche-rohstoffagentur.de/DERA/DE/Downloads/rohstoffliste-2016.pdf?__blob=publicationFile

    In addition, you find some further facts on the website of the Federal Institute for Geosciences and Natural Resources:
    https://www.bgr.bund.de/EN/Themen/Min_rohstoffe/Produkte/produkte_node_en.html?tab=Mineral+Commodity+Facts+and+Figures

    This research is according to the discussion on securing raw materials in the EU and the raw materials criticality are further discussed in detail on the EC website:
    https://ec.europa.eu/growth/sectors/raw-materials/specific-interest/critical_de

    Excerpt:
    „Raw materials are crucial to Europe’s economy. They form a strong industrial base, producing a broad range of goods and applications used in everyday life and modern technologies. Reliable and unhindered access to certain raw materials is a growing concern within the EU and across the globe. To address this challenge, the European Commission has created a list of critical raw materials (CRMs) for the EU, which is subject to a regular review and update. CRMs combine raw materials of high importance to the EU economy and of high risk associated with their supply.“
    HHI The Herfindahl index (also known as Herfindahl–Hirschman Index, HHI, or sometimes HHI-score) is a measure of the size of firms in relation to the industry and an indicator of the amount of competition among them. Named after economists Orris C. Herfindahl and Albert O. Hirschman, it is an economic concept widely applied in competition law, antitrust[1] and also technology management.[2] It is defined as the sum of the squares of the market shares of the firms within the industry (sometimes limited to the 50 largest firms),[3] where the market shares are expressed as fractions. The result is proportional to the average market share, weighted by market share. As such, it can range from 0 to 1.0, moving from a huge number of very small firms to a single monopolistic producer. Increases in the Herfindahl index generally indicate a decrease in competition and an increase of market power, whereas decreases indicate the opposite. Alternatively, if whole percentages are used, the index ranges from 0 to 10,000 "points". For example, an index of .25 is the same as 2,500 points.
    (Source: https://en.wikipedia.org/wiki/Herfindahl_index)
    HSLA High-strength low-alloy steel (HSLA) is a type of alloy steel that provides better mechanical properties or greater resistance to corrosion than carbon steel. HSLA steels vary from other steels in that they are not made to meet a specific chemical composition but rather to specific mechanical properties. They have a carbon content between 0.05–0.25% to retain formability and weldability. Other alloying elements include up to 2.0% manganese and small quantities of copper, nickel, niobium, nitrogen, vanadium, chromium, molybdenum, titanium, calcium, rare earth elements, or zirconium. Copper, titanium, vanadium, and niobium are added for strengthening purposes. These elements are intended to alter the microstructure of carbon steels, which is usually a ferrite-pearlite aggregate, to produce a very fine dispersion of alloy carbides in an almost pure ferrite matrix. This eliminates the toughness-reducing effect of a pearlitic volume fraction yet maintains and increases the material's strength by refining the grain size, which in the case of ferrite increases yield strength by 50% for every halving of the mean grain diameter.
    (Source: https://en.wikipedia.org/wiki/High-strength_low-alloy_steel)
    MRI Magnetic resonance imaging (MRI) is a medical imaging technique used in radiology to form pictures of the anatomy and the physiological processes of the body in both health and disease. MRI scanners use strong magnetic fields, radio waves, and field gradients to generate images of the organs in the body. MRI does not involve x-rays, which distinguishes it from computed tomography (CT or CAT).
    (Source: https://en.wikipedia.org/wiki/Magnetic_resonance_imaging)