MA Reuter
MA Reuter
Chief Expert & Professor: SMS Group Düsseldorf
Verified email at - Homepage
Cited by
Cited by
Informal electronic waste recycling: A sector review with special focus on China
X Chi, M Streicher-Porte, MYL Wang, MA Reuter
Waste management 31 (4), 731-742, 2011
A critical review of lithium-ion battery recycling processes from a circular economy perspective
O Velázquez-Martínez, J Valio, A Santasalo-Aarnio, M Reuter, ...
Batteries 5 (4), 68, 2019
Metal recycling: Opportunities, limits, infrastructure
M Reuter, C Hudson, A Van Schaik, K Heiskanen, C Meskers, ...
A report of the working group on the global metal flows to the international …, 2013
Handbook of Recycling: State-of-the-art for Practitioners, Analysts, and Scientists
E Worrell, MA Reuter
Newnes, 2014
Flotation of mixed copper oxide and sulphide minerals with xanthate and hydroxamate collectors
K Lee, D Archibald, J McLean, MA Reuter
Minerals engineering 22 (4), 395-401, 2009
E-waste collection channels and household recycling behaviors in Taizhou of China
X Chi, MYL Wang, MA Reuter
Journal of Cleaner Production 80, 87-95, 2014
A new paradigm for waste management
GPJ Dijkema, MA Reuter, EV Verhoef
Waste management 20 (8), 633-638, 2000
Recycling and environmental issues of metallurgical slags and salt fluxes
M Reuter, Y Xiao, U Boin
VII International conference on molten slags fluxes and salts, The South …, 2004
Process knowledge, system dynamics, and metal ecology
EV Verhoef, GPJ Dijkema, MA Reuter
Journal of Industrial Ecology 8 (1‐2), 23-43, 2004
Fundamental limits for the recycling of end-of-life vehicles
MA Reuter, A Van Schaik, O Ignatenko, GJ De Haan
Minerals engineering 19 (5), 433-449, 2006
Challenges of the circular economy: a material, metallurgical, and product design perspective
MA Reuter, A van Schaik, J Gutzmer, N Bartie, A Abadías-Llamas
Annual Review of Materials Research 49, 253-274, 2019
Digitalizing the circular economy: Circular economy engineering defined by the metallurgical internet of things
MA Reuter
Metallurgical and Materials transactions B 47, 3194-3220, 2016
Quantifying the quality loss and resource efficiency of recycling by means of exergy analysis
SH Amini, JAM Remmerswaal, MB Castro, MA Reuter
Journal of Cleaner Production 15 (10), 907-913, 2007
Raw material ‘criticality’—sense or nonsense?
M Frenzel, J Kullik, MA Reuter, J Gutzmer
Journal of Physics D: Applied Physics 50 (12), 123002, 2017
Dynamic modelling of E-waste recycling system performance based on product design
A van Schaik, MA Reuter
Minerals Engineering 23 (3), 192-210, 2010
The time-varying factors influencing the recycling rate of products
A Van Schaik, MA Reuter
Resources, Conservation and Recycling 40 (4), 301-328, 2004
The metrics of material and metal ecology: harmonizing the resource, technology and environmental cycles
MA Reuter, UMJ Boin, A Van Schaik, E Verhoef, K Heiskanen, Y Yang, ...
Elsevier, 2005
Simulation-based design for resource efficiency of metal production and recycling systems: Cases-copper production and recycling, e-waste (LED lamps) and nickel pig iron
MA Reuter, A van Schaik, J Gediga
The International Journal of Life Cycle Assessment 20, 671-693, 2015
Aluminium recycling and environmental issues of salt slag treatment
Y Xiao, MA Reuter, UDO Boin
Journal of Environmental Science and Health 40 (10), 1861-1875, 2005
Quantifying the relative availability of high-tech by-product metals–the cases of gallium, germanium and indium
M Frenzel, C Mikolajczak, MA Reuter, J Gutzmer
Resources Policy 52, 327-335, 2017
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