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W3204140753 endingPage "119818" @default.
W3204140753 startingPage "119818" @default.
W3204140753 abstract "In this study, chitosan-grafted-polyacrylamide (Chi-g-PAM), a synthetic biocompatible polymer was investigated as a selective depressant of iron sulfide minerals [i.e., pyrite (FeS2)] in the flotation process of base metal sulfide minerals [i.e., galena (PbS), chalcopyrite (CuFeS2), and sphalerite (ZnS)]. Chi-g-PAM was successfully synthesized by grafting polyacrylamide chains onto chitosan backbone. The synthesized polymer was characterized using Attenuated Total Reflectance-Fourier Transform Infrared Spectroscopy (ATR-FTIR), Nuclear Magnetic Resonance (NMR), Scanning Electron Microscopy (SEM), and X-ray Powder Diffraction (XRD) analysis. Adsorption studies of Chi-g-PAM on mineral surfaces were conducted using zeta potential, contact angle, and total organic carbon (TOC) measurements in addition to X-ray Photoelectron Spectroscopy (XPS). Adsorption tests showed that Chi-g-PAM was most selective to pyrite as compared to the base metal sulfides indicating that this polymer may have the potential to be used as pyrite’s depressant in the flotation of base metal sulfides under specific conditions. XPS studies suggested that the depression of pyrite by Chi-g-PAM was due to chemisorption of the amine, amide, and hydroxyl groups of Chi-g-PAM at pyrite-water interface. The impact of Chi-g-PAM on the flotation response of sulfide minerals was investigated in both microflotation and batch flotation systems using model minerals and real sulfide ore, respectively. In microflotation tests of model minerals, the best separation efficiencies between valuable base metal sulfides and pyrite were achieved at pH 7. In batch flotation tests of complex sulfide ore of Mississippi Valley type (MVT) at natural pH (7.8), a separation efficiency of 61% was achieved between galena and pyrite when Chi-g-PAM was used compared to 35% with sodium cyanide (NaCN), the depressant that is commonly applied for this type of ore. However, the separation efficiency between chalcopyrite and pyrite was 15% and 21% with Chi-g-PAM and NaCN, respectively. Comparative studies indicated that Chi-g-PAM outperformed other depressants at producing less pyrite-diluted flotation concentrates." @default.
W3204140753 created "2021-10-11" @default.
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W3204140753 date "2022-01-01" @default.
W3204140753 modified "2023-10-16" @default.
W3204140753 title "Enhanced separation of base metal sulfides in flotation systems using Chitosan-grafted-Polyacrylamides" @default.
W3204140753 cites W1442839956 @default.
W3204140753 cites W1965958033 @default.
W3204140753 cites W1972594684 @default.
W3204140753 cites W1974276020 @default.
W3204140753 cites W1977998156 @default.
W3204140753 cites W1979177804 @default.
W3204140753 cites W1980778388 @default.
W3204140753 cites W1982480458 @default.
W3204140753 cites W1984953206 @default.
W3204140753 cites W1986589207 @default.
W3204140753 cites W1987845501 @default.
W3204140753 cites W1987921030 @default.
W3204140753 cites W1988141742 @default.
W3204140753 cites W1988357833 @default.
W3204140753 cites W1992182846 @default.
W3204140753 cites W1992381014 @default.
W3204140753 cites W1993462183 @default.
W3204140753 cites W1998796084 @default.
W3204140753 cites W2003007999 @default.
W3204140753 cites W2006011521 @default.
W3204140753 cites W2009410741 @default.
W3204140753 cites W2014774000 @default.
W3204140753 cites W2015170831 @default.
W3204140753 cites W2023794755 @default.
W3204140753 cites W2024266659 @default.
W3204140753 cites W2027072888 @default.
W3204140753 cites W2033714061 @default.
W3204140753 cites W2035999834 @default.
W3204140753 cites W2036357203 @default.
W3204140753 cites W2036389751 @default.
W3204140753 cites W2039499141 @default.
W3204140753 cites W2043014703 @default.
W3204140753 cites W2043168279 @default.
W3204140753 cites W2044775789 @default.
W3204140753 cites W2046712000 @default.
W3204140753 cites W2048696026 @default.
W3204140753 cites W2065775899 @default.
W3204140753 cites W2067402557 @default.
W3204140753 cites W2074142867 @default.
W3204140753 cites W2076167403 @default.
W3204140753 cites W2077388873 @default.
W3204140753 cites W2084409740 @default.
W3204140753 cites W2088418013 @default.
W3204140753 cites W2090276657 @default.
W3204140753 cites W2092801090 @default.
W3204140753 cites W2126025431 @default.
W3204140753 cites W2149712313 @default.
W3204140753 cites W2170718805 @default.
W3204140753 cites W2321051485 @default.
W3204140753 cites W2326358798 @default.
W3204140753 cites W2412787814 @default.
W3204140753 cites W2467925560 @default.
W3204140753 cites W2569857594 @default.
W3204140753 cites W2625146183 @default.
W3204140753 cites W2762851421 @default.
W3204140753 cites W2769783125 @default.
W3204140753 cites W2773843318 @default.
W3204140753 cites W2805650525 @default.
W3204140753 cites W2811171885 @default.
W3204140753 cites W2863672112 @default.
W3204140753 cites W2887756014 @default.
W3204140753 cites W2888699349 @default.
W3204140753 cites W2912722395 @default.
W3204140753 cites W2951347986 @default.
W3204140753 cites W2963270159 @default.
W3204140753 cites W2965954091 @default.
W3204140753 cites W2973003136 @default.
W3204140753 cites W3035639675 @default.
W3204140753 cites W3040044835 @default.
W3204140753 cites W4238175171 @default.
W3204140753 cites W4246086157 @default.
W3204140753 cites W4247072407 @default.
W3204140753 cites W764180164 @default.
W3204140753 doi "https://doi.org/10.1016/j.seppur.2021.119818" @default.
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