Removal of metals from water using stabilized and “green” method produced nano iron (0)

Abstract

<p>Predmet izučavanja ove disertacije je ispitivanje mogućnosti&nbsp; primene stabilisanog nano Fe(0)&nbsp; i &bdquo;zelenom&ldquo; sintezom produkovanog nano&nbsp; Fe(0)&nbsp; u uklanjanju Cr(VI), Cd(II), Cu(II), Ni(II), Pb(II) i As(III)&nbsp; iz vode.&nbsp; Sinteza nano Fe(0) za stabilizaciju izvr&scaron;ena je konvencionalnom metodom&nbsp; redukcije gvožđa sa natrijum borhidridom&nbsp; u prisustvu materijala za stabilizaciju: kaolinita,&nbsp; bentonita i karboksimetil celuloze. Za &bdquo;zelenu&rdquo; sintezu nano Fe(0) kori&scaron;ćeno je li&scaron;će drveća: hrasta, duda i vi&scaron;nje.&nbsp; Karakterizacija&nbsp; dobijenih nanomaterijala izvr&scaron;ena je transmisionom i skenirajućom elektronskom mikroskopijom. Rezultati karakterizacije su pokazali da se tokom sinteze nano Fe(0) natrijum borhidridom i stabilizacije kaolinitom, bentonitom i karboksimetil celulozom, formiraju nano čestice Fe(0) veličine 20 do 90 nm, dok su veličine čestica nano Fe(0) sintetisanih &bdquo;zelenom&ldquo; metodom iznosile 10-30 nm i okarakterisane su kao nano čestice sfernog oblika, različitih veličina bez značajane aglomeracije.&nbsp; Primena nano&nbsp;Fe(0) na efikasnost&nbsp; uklanjanja metala iz vode ispitivana je pri različitim uslovima:&nbsp; uticaju doze nanomaterijala, početne koncentracije&nbsp; metala, pH vrednosti rastvora i kontaktnog vremena.&nbsp; Dobijeni rezultati prilikom ispitivanja uticaja&nbsp; doze nanomaterijala&nbsp; na efikasnosti uklanjanja odabranih metala iz vode primenom stabilisanih i &bdquo;zelenih&ldquo; nanomaterijala&nbsp; pokazali&nbsp; su&nbsp; da se povećanjem doze nanomaterijala&nbsp; povećava efikasnost uklanjanja.&nbsp; Prilikom primene stabilisanih nanomaterijala, koncentracije 14.00 gFe(0)/l,&nbsp; postignute&nbsp; su visoke efikasnosti uklanjanja, već pri dozama od&nbsp; 2 ml, dok je efikasnost uklanjanja primenom&nbsp; &bdquo;zelenih&ldquo; nanomaterijala koncentracije 1,395 gFe(0)/l bila niža. Prilikom ispitivanja uticaja pH vrednosti na uklanjanje metala iz vode primenom ispitivanih nanomaterijala, određeni &nbsp;su optimalni opsezi pH vrednosti pri kojima se postiže najveća adsorpcija metala&nbsp; na ispitivanim nanomaterijalima.&nbsp; Veza između metala&nbsp; i&nbsp; ispitivanih nanomaterijala obja&scaron;njena je modelovanjem Langmuir-ove i Freunlich-ove&nbsp; adsorpcione izoterme. Veće adsorpcione kapacitete prilikom adsorpcije svih ispitivanih metala pokazali su nanomaterijali produkovani &bdquo;zelenom&ldquo; sintezom u odnosu na stabilisane nanomaterijale, &scaron;to je povezano sa veličinom čestica, tj. manje nanočestice nanomaterijala produkovanih &bdquo;zelenom&rdquo; sintezom imaju veću&nbsp; specifičnu povr&scaron;inu i samim tim mogu&nbsp; ponuditi&nbsp; vi&scaron;e reaktivnih mesta, veću reaktivnost i bolju disperziju. Ispitivanje kinetike adsorcije&nbsp; Cr(VI), Cd(II), Cu(II), Ni(II), Pb(II) i As(III) na ispitivanim stabilisanim i &bdquo;zelenom&ldquo; sintezom produkovanim nanomaterijalima pokazalo je veoma brzu reakciju adsorpcije metala na ispitivanim&nbsp;nanomaterijalima i&nbsp; bolje slaganje eksperimentalno dobijenih podataka sa pseudo-drugim kinetičkim modelom.&nbsp; Rezultati dobijeni u ovom&nbsp; istraživanju omogućiće procenu&nbsp; primene nano Fe(0) za uklanjanje metala iz vode, posebno adsorpciju metala iz vode kao i odabir najefikasnijeg i najekonomičnijeg adsorbensa za uklanjanje različitih metala iz vode.</p>

<p>This work is concerned with exploring the possibility&nbsp; of&nbsp; application of&nbsp; stabilized nano Fe(0)&nbsp; and nano Fe (0) produced by &ldquo;green&rdquo; synthesis&nbsp; in the&nbsp; removal&nbsp; of Cr(VI), Cd(II), Cu(II), Ni(II), Pb(II)&nbsp; and&nbsp; As(III)&nbsp; from&nbsp; the&nbsp; water.&nbsp; Synthesis of nano Fe(0) for the stabilization is carried out according to conventional method of iron reduction with sodium borohydride in the presence of a material for stabilization: kaolinite, bentonite and carboxymethyl cellulose. Leaves of oak, mulberry and cherry trees used for&nbsp; &ldquo;green&rdquo;&nbsp; synthesis of nano Fe(0). Characterization of nanomaterials&nbsp; was performed by transmission and scanning electron microscopy.&nbsp; The&nbsp; characterization&nbsp; results&nbsp; have shown that during the synthesis and stabilization of nano Fe (0) process formed nanoparticles with size from 20 to 90 nm, while the nano Fe (0) particles synthesized by &quot;green&quot; method were within the&nbsp; size of&nbsp; 10-30 nm and characterized as spherical nanoparticles with&nbsp; various sizes without significant agglomeration.&nbsp; Application of nano Fe (0) on the&nbsp; removal&nbsp; efficiency of&nbsp; metals from water was studied under different conditions: the influence of&nbsp; nanomaterials&nbsp; dose, the initial metal concentrations, pH value of the solution&nbsp; and the contact time. The results obtained during the examination of the impact of nanomaterial&nbsp; dose&nbsp; on the&nbsp; removal&nbsp; efficiency&nbsp; of selected metals from water&nbsp; have shown that increasing&nbsp; of nanomaterial&nbsp; dose increases removal efficiency. High removal efficiency is achieved when used&nbsp; 2 ml of stabilized nanomaterials, concentration of 14.00 gFe(0)/L, while when &quot;green&quot; nanomaterials,&nbsp; concentration&nbsp; of&nbsp; 1,395&nbsp; gFe(0)/L,&nbsp; were&nbsp; used&nbsp; the removal efficiency&nbsp; was&nbsp; lower.&nbsp; The optimal ranges of pH values&nbsp; at which&nbsp; the tested&nbsp; nanomaterials&nbsp; reach the maximum adsorption of metals&nbsp; were obtained, during the examination of&nbsp; the influence of pH value on removal of metals from water by using the tested nanomaterials&nbsp; The&nbsp; relation&nbsp; between&nbsp; the metals&nbsp; and tested&nbsp;&nbsp; nanomaterials is explained by modeling&nbsp; of&nbsp; Langmuir&#39;s and Freunlich&#39;s adsorption isotherm.&nbsp; Nanomaterials&nbsp; produced&nbsp; by&nbsp; &quot;green&quot; synthesis&nbsp; showed higher&nbsp; adsorption capacity&nbsp; than&nbsp; stabilized&nbsp; nanomaterials, which is related&nbsp; with particle size, i.e. the&nbsp; nanoparticles&nbsp; produced by&nbsp; &quot;green&quot; synthesis&nbsp; have&nbsp; less particles, higher specific surface area and therefore can offer more reactive sites, greater reactivity and better dispersion. Kinetics&nbsp; tests&nbsp; showed a very fast adsorption of metal&nbsp; on&nbsp; the tested nanomaterials and better agreement with the experimental data to&nbsp; second&nbsp; pseudo-kinetic model.&nbsp; The results obtained in this study will enable the assessment of the application of nano&nbsp; Fe (0) for the removal of metals from water, especially for the adsorption of metals from water as well as the selection of the most&nbsp; efficient and most economical of the adsorbent for the removal of various metals from water.</p>