Biossorção de azul de metileno utilizando resíduos agroindustriais

Abstract: R E S U M OO presente trabalho avaliou a capacidade de adsorção do corante azul de metileno nos resíduos da palha de milho e da bainha do palmito pupunha in natura. A caracterização dos resíduos foi determinada utilizando-se a microscopia eletrônica de varredura e espectroscopia na região do infravermelho a qual indicou a presença de grupos carboxílicos, hidroxila e carbonila. O tempo necessário para que o sistema atingisse o equilíbrio para ambos os resíduos foi de 240 min, seguindo uma cinética descrita pelo… Show more

“…The Scanning Electron Microscopy images of PTM and CCLHR are shown in Figure 2 with magnification of 2190× and 1720×, respectively The SEM analyzes showed a large amount of pores implying a wide surface area, which facilitates the MB biosorption process [40]. This indicates a necessary requirement of these lignocellulosic materials as potential biosorbents.…”

“…Various biosorbents have been applied in removal MB from the aqueous solution, as reported in the previous literature, for comparison purposes. We can compare the results with other authors in term the maximum capacity adsorbed in the conditions optimized by each authors: Carica papaya wood false(qmax=32.25 mg·g−1) [41], Cornbread false(qmax=106.383 mg·g−1false) and pupunha palm false(qmax=78.989 mg·g−1false) [40], Potato shell false(qmax=48.7 mg·g−1false) [64], Scenedesmus false(qmax=61.69 mg·g−1false) [65]. Through the comparative study with the Table 2, we can conclude that PMT and CCLHR are between the most efficient adsorbents prepared for industrial wastewater treatment.…”

“…Several works that deal with the removal of methylene blue are presented in the literature using biosorbents obtained from lignocellulosic materials in the in natura form such as coconut fiber [33], banana peel [34], mint tailings [35], pineapple peel [36], cashew nutshell [37] pine leaves [38], tea residues [39], corn straw, pupunha palm [40], trunk of the papaya tree [41]. In this paper, the biosorbents presented for the removal of methylene blue dye (MB) were produced from weeds that can be defined as any plants that grow spontaneously in a place of human activity and cause damage to this activity, be it agricultural, forestry, livestock, ornamental, nautical, energy production etc.…”

Biosorption of Methylene Blue Dye Using Natural Biosorbents Made from Weeds

“…The Scanning Electron Microscopy images of PTM and CCLHR are shown in Figure 2 with magnification of 2190× and 1720×, respectively The SEM analyzes showed a large amount of pores implying a wide surface area, which facilitates the MB biosorption process [40]. This indicates a necessary requirement of these lignocellulosic materials as potential biosorbents.…”

“…Various biosorbents have been applied in removal MB from the aqueous solution, as reported in the previous literature, for comparison purposes. We can compare the results with other authors in term the maximum capacity adsorbed in the conditions optimized by each authors: Carica papaya wood false(qmax=32.25 mg·g−1) [41], Cornbread false(qmax=106.383 mg·g−1false) and pupunha palm false(qmax=78.989 mg·g−1false) [40], Potato shell false(qmax=48.7 mg·g−1false) [64], Scenedesmus false(qmax=61.69 mg·g−1false) [65]. Through the comparative study with the Table 2, we can conclude that PMT and CCLHR are between the most efficient adsorbents prepared for industrial wastewater treatment.…”

“…Several works that deal with the removal of methylene blue are presented in the literature using biosorbents obtained from lignocellulosic materials in the in natura form such as coconut fiber [33], banana peel [34], mint tailings [35], pineapple peel [36], cashew nutshell [37] pine leaves [38], tea residues [39], corn straw, pupunha palm [40], trunk of the papaya tree [41]. In this paper, the biosorbents presented for the removal of methylene blue dye (MB) were produced from weeds that can be defined as any plants that grow spontaneously in a place of human activity and cause damage to this activity, be it agricultural, forestry, livestock, ornamental, nautical, energy production etc.…”

Biosorption of Methylene Blue Dye Using Natural Biosorbents Made from Weeds

“…Os valores de q max obtidos pelo modelo de Langmuir para a fibra de coco in natura e tratada refletem elevada capacidade adsortiva, para azul de metileno, em relação a outros materiais adsorventes reportados na literatura, tais como, palmito pupunha (q max = 50,96 mg g -1 ) [36]; bagaço de cana-de-açúcar (q max = 31,79 mg g -1 ) [37] e casca de maracujá (q max = 44,70 mg g -1 ) [38], sendo a fibra de coco tratada com HCl a que apresentou maior capacidade adsortiva (166,67 mg g -1 ), quando comparada aos demais tratamentos, in natura e tratados com NaOH e hexano.…”

Avaliação de processo adsortivo utilizando mesocarpo de coco verde para remoção do corante azul de metileno

“…Assim, as capacidades máximas de adsorção foram observadas em 45°C, atingindo 223,9 mg g -1 para o PR5 e 427,9 mg g -1 para o AM. Especialmente no caso do AM, nota-se que em comparação à capacidade máxima de adsorção obtida para outros materiais a 25°C, como palha de milho (102,8 mg g -1 ) e resíduo do palmito pupunha (50,9 mg g -1 ) (Honorato et al, 2015) e fibra de ouricuri (29,8 mg g -1 ) (Silva et al, 2015),o desempenho alcançado com a fibra de piaçava revelou-se muito superior (328,8 mg g -1 ).…”

Fibra De Piaçava: Adsorvente Alternativo Na Remoção De Azul De Metileno E Preto Reativo 5 De Soluções Aquosas