Elimination of dyes by catalytic reduction in the absence of light: A review

1.

Chiou J-R et al (2013) One-pot green synthesis of silver/iron oxide composite nanoparticles for 4-nitrophenol reduction. J Hazard Mater 248–249:394–400CrossRef

2.

Pabbathi NPP et al (2020) Environmental metabolomics: with the perspective of marine toxicology assessment, in environmental biotechnology. Springer, Newyork

3.

Tiwari DK, Behari J, Sen P (2008) Application of nanoparticles in waste water treatment 1.

4.

Jiang J-Q, Ashekuzzaman SM (2012) Development of novel inorganic adsorbent for water treatment. Curr Opin Chem Eng 1(2):191–199CrossRef

5.

Margalef-Marti R et al (2019) Evaluating the potential use of a dairy industry residue to induce denitrification in polluted water bodies: A flow-through experiment. J Environ Manage 245:86–94CrossRef

6.

Elimelech M (2006) The global challenge for adequate and safe water. J Water Supply Res Technol–AQUA, 55(1): 3–10.

7.

Tabassum S (2019) A combined treatment method of novel mass bio system and ion exchange for the removal of ammonia nitrogen from micro-polluted water bodies. Chem Eng J 378:122217CrossRef

8.

Fawell J, Nieuwenhuijsen MJ (2003) Contaminants in drinking water environmental pollution and health. Br Med Bull 68(1):199–208CrossRef

9.

Kass A et al (2005) The impact of freshwater and wastewater irrigation on the chemistry of shallow groundwater: a case study from the Israeli Coastal Aquifer. J Hydrol 300(1–4):314–331CrossRef

10.

Al Yaqout AF (2003) Assessment and analysis of industrial liquid waste and sludge disposal at unlined landfill sites in arid climate. Waste Manage 23(9):817–824CrossRef

11.

Bhatnagar A, Sillanpää M (2009) Applications of chitin-and chitosan-derivatives for the detoxification of water and wastewater–a short review. Adv Coll Interface Sci 152(1):26–38CrossRef

12.

Bhatnagar A, Sillanpää M (2010) Utilization of agro-industrial and municipal waste materials as potential adsorbents for water treatment–A review. Chem Eng J 157(2):277–296CrossRef

13.

Bhatnagar A, Sillanpää M (2011) A review of emerging adsorbents for nitrate removal from water. Chem Eng J 168(2):493–504CrossRef

14.

Qu X, Alvarez PJJ, Li Q (2013) Applications of nanotechnology in water and wastewater treatment. Water Res 47(12):3931–3946CrossRef

15.

Raza A et al (2019) Enhanced industrial dye degradation using Co doped in chemically exfoliated MoS2 nanosheets. Appl Nanosci 10(5):1535–1544CrossRef

16.

Ikram M et al (2020) Photocatalytic and bactericidal properties and molecular docking analysis of TiO2 nanoparticles conjugated with Zr for environmental remediation. RSC Adv 10(50):30007–30024CrossRef

17.

Zollinger H (2000) Azo dyes and pigments. Colour Chem-Syn, Properties Appl Organic Dyes Pigments 1987:92–100

18.

Bafana A, Devi SS, Chakrabarti T (2011) Azo dyes: past, present and the future. Environ Rev 19:350–371CrossRef

19.

Mark HF et al (1978) Encyclopedia of chemical technology. Wiley, London

20.

Ikram M et al (2020) Dye degradation performance, bactericidal behavior and molecular docking analysis of Cu-doped TiO2 nanoparticles. RSC Adv 10(41):24215–24233CrossRef

21.

Rafiq A, et al. (2021) Photocatalytic degradation of dyes using semiconductor photocatalysts to clean industrial water pollution. J Ind Eng Chem.

22.

Naz M et al (2018) Bio-inspired synthesis of silver nanoparticles: anticancer drug carrier, catalytic and bactericidal potential. Nanosci Nanotechnol Lett 10(7):889–899CrossRef

23.

Vanhulle S et al (2008) Decolorization, cytotoxicity, and genotoxicity reduction during a combined ozonation/fungal treatment of dye-contaminated wastewater. Environ Sci Technol 42(2):584–589CrossRef

24.

Pereira L, Alves M (2012) Dyes—environmental impact and remediation, in Environmental protection strategies for sustainable development. Springer, Newyork

25.

Ikram M et al (2020) Outstanding performance of silver-decorated MoS2 nanopetals used as nanocatalyst for synthetic dye degradation. Phys E Low-dimensional Syst Nanostruct 124:114246CrossRef

26.

Ikram M et al (2020) Promising performance of chemically exfoliated Zr-doped MoS2 nanosheets for catalytic and antibacterial applications. RSC Adv 10(35):20559–20571CrossRef

27.

Martínez-Huitle CA, Brillas E (2009) Decontamination of wastewaters containing synthetic organic dyes by electrochemical methods: a general review. Appl Catal B 87(3–4):105–145CrossRef

28.

Taghizadeh A, Rad-Moghadam K (2018) Green fabrication of Cu/pistachio shell nanocomposite using Pistacia Vera L. hull: An efficient catalyst for expedient reduction of 4-nitrophenol and organic dyes. J Cleaner Prod 198:1105–1119CrossRef

29.

Ikram M et al (2020) 2D chemically exfoliated hexagonal boron nitride (hBN) nanosheets doped with Ni: synthesis, properties and catalytic application for the treatment of industrial wastewater. Appl Nanosci 10(9):3525–3528CrossRef

30.

Raza A et al (2020) A comparative study of dirac 2D materials, TMDCs and 2D insulators with regard to their structures and photocatalytic/sonophotocatalytic behavior. Appl Nanosci 10(10):3875–3899CrossRef

31.

Zhang Z et al (2015) A highly reactive and magnetic recyclable catalytic system based on AuPt nanoalloys supported on ellipsoidal Fe@ SiO 2. J Mater Chem A 3(8):4642–4651CrossRef

32.

Ikram M et al (2020) Reduced graphene oxide nanosheets doped by Cu with highly efficient visible light photocatalytic behavior. J Alloys Comp 837:155588CrossRef

33.

Padhi B (2012) Pollution due to synthetic dyes toxicity carcinogenicity studies and remediation. Int J Environ Sci 3(3):940–955

34.

Ajmal A et al (2014) Principles and mechanisms of photocatalytic dye degradation on TiO2 based photocatalysts: a comparative overview. RSC Adv 4(70):37003–37026CrossRef

35.

Ikram M et al (2020) Hydrothermal Synthesis of Silver Decorated Reduced Graphene Oxide (rGO) Nanoflakes with Effective Photocatalytic Activity for Wastewater Treatment. Nanoscale Res Lett 15(1):95CrossRef

36.

Srivastava V, Choubey AK (2019) Synthesis of nanostructured silver particles using Citrus limetta peel extract for catalytic degradation of azo dyes through electron relay effect. Adv Nat Sci Nanosci Nanotechnol 10(4):045015CrossRef

37.

Kaur G et al (2020) Blooming approach: one-pot biogenic synthesis of TiO2 nanoparticles using piper betle for the degradation of industrial reactive yellow 86 Dye. J Inorganic Organometall Polymers Mater 31(3):1111–1119CrossRef

38.

Mallakpour S, Behranvand V, Mallakpour F (2019) Synthesis of alginate/carbon nanotube/carbon dot/fluoroapatite/TiO2 beads for dye photocatalytic degradation under ultraviolet light. Carbohyd Polym 224:115138CrossRef

39.

Naz M et al (2017) Green synthesis (A. indica seed extract) of silver nanoparticles (Ag-NPs), characterization, their catalytic and bactericidal action potential. Nanosci and Nanotechnol Lett 9(11):1649–1655CrossRef

40.

Xiong P et al (2012) Multi-walled carbon nanotubes supported nickel ferrite: a magnetically recyclable photocatalyst with high photocatalytic activity on degradation of phenols. Chem Eng J 195–196:149–157CrossRef

41.

Rafiq A et al (2019) ZnS–Ni doped nanoparticles served as promising nano-photocatalyst (industrial dye degrader). Nanosci Nanotechnol Lett 11(8):1060–1069CrossRef

42.

Maurino V et al (1997) The fate of organic nitrogen under photocatalytic conditions: degradation of nitrophenols and aminophenols on irradiated TiO2. J Photochem Photobiol, A 109(2):171–176CrossRef

43.

Singh J, A.J.E.t. Dhaliwal, (2020) Plasmon-induced photocatalytic degradation of methylene blue dye using biosynthesized silver nanoparticles as photocatalyst. Environmen Technol 41(12):1520–1534

44.

Soler L, Sánchez S (2014) Catalytic nanomotors for environmental monitoring and water remediation. Nanoscale 6(13):7175–7182CrossRef

45.

Parasuraman D, Serpe MJ (2011) Poly (N-isopropylacrylamide) microgels for organic dye removal from water. ACS Appl Mater Interfaces 3(7):2732–2737CrossRef

46.

Ahmad M et al (2014) Photocatalytic, sonocatalytic and sonophotocatalytic degradation of Rhodamine B using ZnO/CNTs composites photocatalysts. Ultrason Sonochem 21(2):761–773CrossRef

47.

Zhou L et al (2016) The roles of conjugations of graphene and Ag in Ag 3 PO 4-based photocatalysts for degradation of sulfamethoxazole. Catal Sci Technol 6(15):5972–5981CrossRef

48.

Khehra MS et al (2005) Comparative studies on potential of consortium and constituent pure bacterial isolates to decolorize azo dyes. Water Res 39(20):5135–5141CrossRef

49.

Xiao F et al (2016) Synthesis of akageneite (beta-FeOOH)/reduced graphene oxide nanocomposites for oxidative decomposition of 2-chlorophenol by Fenton-like reaction. J Hazard Mater 308:11–20CrossRef

50.

Yu F et al (2014) A novel electro-Fenton process with H2O2 generation in a rotating disk reactor for organic pollutant degradation. Environ Sci Technol Lett 1(7):320–324CrossRef

51.

Donaldson JD et al (2002) Anodic oxidation of the dye materials methylene blue, acid blue 25, reactive blue 2 and reactive blue 15 and the characterisation of novel intermediate compounds in the anodic oxidation of methylene blue. J Chem Technol Biotechnol Int Res Process Environ Clean Technol 77(7):756–760

52.

Apolinário ÂC et al (2008) Wet air oxidation of nitro-aromatic compounds: Reactivity on single- and multi-component systems and surface chemistry studies with a carbon xerogel. Appl Catal B 84(1):75–86CrossRef

53.

Li Y et al (2020) Preparation of CoFe2O4–P4VP@Ag NPs as effective and recyclable catalysts for the degradation of organic pollutants with NaBH4 in water. Int J Hydrogen Energy 45(32):16080–16093CrossRef

54.

Narayanan RK, Devaki SJ (2015) Brawny silver-hydrogel based nanocatalyst for reduction of nitrophenols: studies on kinetics and mechanism. Ind Eng Chem Res 54(4):1197–1203CrossRef

55.

Zhu X, Ni J (2011) The improvement of boron-doped diamond anode system in electrochemical degradation of p-nitrophenol by zero-valent iron. Electrochim Acta 56(28):10371–10377CrossRef

56.

Singh S, Kumar N, Kumar M, Jyoti Agarwal A, Mizaikoff B (2017) Electrochemical sensing and remediation of 4-nitrophenol using bio-synthesized copper oxide nanoparticles. Chem Eng J 4:283–292CrossRef

57.

Zaggout FR, Abu Ghalwa N (2008) Removal of o-nitrophenol from water by electrochemical degradation using a lead oxide/titanium modified electrode. J Environ Manag 86(1):291–296CrossRef

58.

Wu Z et al (2012) Size-controlled synthesis of a supported Ni nanoparticle catalyst for selective hydrogenation of p-nitrophenol to p-aminophenol. Catal Commun 18:55–59CrossRef

59.

Chen R, et al (2007) Effect of alumina particle size on Ni/Al2O3 Catalysts for p-nitrophenol hydrogenation* *Supported by the Special Funds for Major State Basic Research Program of China (No.2003CB615702), the National Natural Science Foundation of China (No.20636020) and the Natural Science Foundation of Jiangsu Province(No.BK2006722). Chinese J Chem Eng, 15(6): p. 884–888.

60.

Dai R et al (2009) Reduction of nitro phenols using nitroreductase from E coli in the presence of NADH. J Hazardous Mater 170(1):141–143CrossRef

61.

Li L et al (2013) Transformation of cefazolin during chlorination process: Products, mechanism and genotoxicity assessment. J Hazard Mater 262:48–54CrossRef

62.

Rodríguez-León E et al (2019) Synthesis of gold nanoparticles using mimosa tenuiflora extract, assessments of cytotoxicity, cellular uptake, and catalysis. Nanoscale Res Lett 14(1): 334

63.

Zhang A et al (2012) Heterogeneous Fenton-like catalytic removal of p-nitrophenol in water using acid-activated fly ash. J Hazard Mater 201:68–73CrossRef

64.

Ganzenko O et al (2018) Bioelectro-Fenton: evaluation of a combined biological—advanced oxidation treatment for pharmaceutical wastewater. Environ Sci Pollut Res 25(21):20283–20292CrossRef

65.

Madrakian T, Afkhami A, Ahmadi MJC (2013) Simple in situ functionalizing magnetite nanoparticles by reactive blue-19 and their application to the effective removal of Pb2+ ions from water samples. Chemosphere 90(2):542–547CrossRef

66.

Luo Y et al (2014) A review on the occurrence of micropollutants in the aquatic environment and their fate and removal during wastewater treatment. Sci Total Environ 473:619–641CrossRef

67.

da Silva MER, PIM. Firmino ABJBt. (2012) dos Santos, Impact of the redox mediator sodium anthraquinone-2, 6-disulphonate (AQDS) on the reductive decolourisation of the azo dye Reactive Red 2 (RR2) in one-and two-stage anaerobic systems. Bioresource technology. 121: 1–7.

68.

Lichtfouse CG, EJECL, (2019) Advantages and disadvantages of techniques used for wastewater treatment. Environ Chem Lett 17(1):145–155CrossRef

69.

Robinson T et al (2001) Remediation of dyes in textile effluent: a critical review on current treatment technologies with a proposed alternative. Biores Technol 77(3):247–255CrossRef

70.

Gupta N, Singh HP, Sharma RK (2011) Metal nanoparticles with high catalytic activity in degradation of methyl orange: an electron relay effect. J Mol Catal A: Chem 335(1–2):248–252CrossRef

71.

Safavi A, Momeni S (2012) Highly efficient degradation of azo dyes by palladium/hydroxyapatite/Fe3O4 nanocatalyst. J Hazard Mater 201:125–131CrossRef

72.

Amir M, Kurtan U, Baykal A (2015) Rapid color degradation of organic dyes by Fe3O4@ His@ Ag recyclable magnetic nanocatalyst. J Ind Eng Chem 27:347–353CrossRef

73.

Zheng L-Q et al (2015) Reversible catalysis for the reaction between methyl orange and NaBH 4 by silver nanoparticles. Chem Commun 51(6):1050–1053CrossRef

74.

Rostami-Vartooni A, Nasrollahzadeh M, Alizadeh M (2016) Green synthesis of seashell supported silver nanoparticles using Bunium persicum seeds extract: application of the particles for catalytic reduction of organic dyes. J Colloid Interface Sci 470:268–275CrossRef

75.

Bian S-W, Liu S, Chang L (2016) Synthesis of magnetically recyclable Fe 3 O 4@ polydopamine–Pt composites and their application in hydrogenation reactions. J Mater Sci 51(7):3643–3649. https://doi.org/10.1007/s10853-015-9688-3CrossRef

76.

Francis S et al (2019) Catalytic activities of green synthesized silver and gold nanoparticles. Mater Today Proc 9:97–104CrossRef

77.

Zhong X et al (2020) The magnetic covalent organic framework as a platform for high-performance extraction of Cr (VI) and bisphenol a from aqueous solution. J Hazardous Mater 393:122353CrossRef

78.

Zhu Y et al (2020) Cultivation of granules containing anaerobic decolorization and aerobic degradation cultures for the complete mineralization of azo dyes in wastewater. Chemosphere 246:125753CrossRef

79.

Zelekew OA, Kuo D-H (2016) A two-oxide nanodiode system made of double-layered p-type Ag 2 O@ n-type TiO 2 for rapid reduction of 4-nitrophenol. Phys Chem Chem Phys 18(6):4405–4414CrossRef

80.

Ikram M et al (2020) Bimetallic Ag/Cu incorporated into chemically exfoliated MoS2 nanosheets to enhance its antibacterial potential: in silico molecular docking studies. Nanotechnology 31(27):275704CrossRef

81.

Quiton KGN, Lu M-C, Huang Y-H (2021) Synthesis and catalytic utilization of bimetallic systems for wastewater remediation: a review. Chemosphere 262:128371CrossRef

82.

Albukhari SM et al (2019) Catalytic reduction of nitrophenols and dyes using silver nanoparticles @ cellulose polymer paper for the resolution of waste water treatment challenges. Colloids Surf, A 577:548–561CrossRef

83.

Nagarajan D, Venkatanarasimhan S (2019) Copper(II) oxide nanoparticles coated cellulose sponge—an effective heterogeneous catalyst for the reduction of toxic organic dyes. Environ Sci Pollut Res 26(22):22958–22970CrossRef

84.

Kılıç Depren S et al (2020) Ultra-layered sheet CuCo nanoparticles for optimized application in catalytic reduction of organic dye. Mater Characterization 160:110116CrossRef

85.

Zhang P et al (2014) A novel approach for the in situ synthesis of Pt–Pd nanoalloys supported on Fe3O4@ C core–shell nanoparticles with enhanced catalytic activity for reduction reactions. ACS Appl Mater Interfaces 6(4):2671–2678CrossRef

86.

Roberts EJ et al (2019) Continuous flow methods of fabricating catalytically active metal nanoparticles. ACS Appl Mater Interfaces 11(31):27479–27502CrossRef

87.

Zhang N et al (2020) Efficient oxidative degradation of fluconazole by a heterogeneous Fenton process with Cu-V bimetallic catalysts. Chem Eng J 380:122516CrossRef

88.

Oseghale CI et al (2019) Gold-based carbon-supported bimetallic catalysts for energy storage and biomedical applications. Microchem J 149:103917CrossRef

89.

Wang P et al (2020) Nano-hybrid bimetallic Au-Pd catalysts for ambient condition-catalytic wet air oxidation (AC-CWAO) of organic dyes. Separation and Purification Technol 233:115960CrossRef

90.

Soltani M, Zabihi M (2020) Hydrogen generation by catalytic hydrolysis of sodium borohydride using the nano-bimetallic catalysts supported on the core-shell magnetic nanocomposite of activated carbon. Int J Hydrogen Energy 45(22):12331–12346CrossRef

91.

Pozun ZD et al (2013) A systematic investigation of p-nitrophenol reduction by bimetallic dendrimer encapsulated nanoparticles. The J Phys Chem C 117(15):7598–7604CrossRef

92.

Hasnat MA et al (2015) Aggregated Pt–Pd nanoparticles on Nafion membrane for impulsive decomposition of hydrogen peroxide. RSC Adv 5(57):46295–46300CrossRef

93.

Wang Y-X et al (2020) Ligand-enabled Ni–Al bimetallic catalysis for nonchelated dual C-H annulation of arylformamides and alkynes. Org Lett 22(6):2230–2234CrossRef

94.

Gu Y et al (2019) Solvent effect on the solvothermal synthesis of mesoporous NiO catalysts for activation of peroxymonosulfate to degrade organic dyes. ACS Omega 4(18):17672–17683CrossRef

95.

Lee J-SM et al (2019) Homogenized bimetallic catalysts from metal-organic framework alloys. Chem Mater 31(11):4205–4212CrossRef

96.

Mei S et al (2020) Organic–inorganic bimetallic hybrid particles with controllable morphology for the catalytic degradation of organic dyes. J Hazard Mater 44(20):8366–8378

97.

Park H et al (2017) Hydrogenation of 4-nitrophenol to 4-aminophenol at room temperature: Boosting palladium nanocrystals efficiency by coupling with copper via liquid phase pulsed laser ablation. Appl Surf Sci 401:314–322CrossRef

98.

Ma, B., et al. (2019) Bimetal–organic-framework-derived nanohybrids Cu0.9Co2.1S4@MoS2 for high-performance visible-light-catalytic hydrogen evolution reaction. ACS Appl Energy Mater, 2(2): 1134–1148.

99.

Zhang K et al (2020) Insights into the active sites of chlorine-resistant Pt-based bimetallic catalysts for benzene oxidation. Appl Catalysis B Environ 279:119372CrossRef

100.

Rui N et al (2021) Highly active Ni/CeO2 catalyst for CO2 methanation: Preparation and characterization. Appl Catalysis B Environ 282:119581CrossRef

101.

Jiang Z, Guo S, Fang T (2019) Enhancing the Catalytic Activity and Selectivity of PdAu/SiO2 Bimetallic Catalysts for Dodecahydro-N-ethylcarbazole Dehydrogenation by Controlling the Particle Size and Dispersion. ACS Appl Energy Mater 2(10):7233–7243CrossRef

102.

Pan Y-T, Yang H (2020) Design of bimetallic catalysts and electrocatalysts through the control of reactive environments. Nano Today 31:100832CrossRef

103.

Peng W et al (2011) Selective reduction of 4, 4′-dinitrostilbene-2, 2′-disulfonic acid catalyzed by supported nano-sized gold with sodium formate as hydrogen source. Catal Commun 12(6):568–572CrossRef

104.

Hatamifard A, Nasrollahzadeh M, Lipkowski JJRa (2015) Green synthesis of a natrolite zeolite/palladium nanocomposite and its application as a reusable catalyst for the reduction of organic dyes in a very short time. RSC Adv 5(111):91372–91381CrossRef

105.

Khan MM, Lee J, Cho MH (2014) Au@ TiO2 nanocomposites for the catalytic degradation of methyl orange and methylene blue: an electron relay effect. J Ind Eng Chem 20(4):1584–1590CrossRef

106.

Kumar Y et al (2020) Nitrogen-rich and porous graphitic carbon nitride nanosheet-immobilized palladium nanoparticles as highly active and recyclable catalysts for the reduction of nitro compounds and degradation of organic dyes. ACS Omega 5(22):13250–13258CrossRef

107.

Zhang K et al (2019) Recent advances in the nanocatalyst-assisted nabh4 reduction of nitroaromatics in water. ACS Omega 4(1):483–495CrossRef

108.

Xi Z et al (2013) Study the catalyzing mechanism of dissolved redox mediators on bio-denitrification by metabolic inhibitors. Biores Technol 140:22–27CrossRef

109.

Lu H et al (2014) A novel quinone/reduced graphene oxide composite as a solid-phase redox mediator for chemical and biological Acid Yellow 36 reduction. RSC Adv 4(88):47297–47303CrossRef

110.

Kirchon A et al (2020) Effect of isomorphic metal substitution on the fenton and photo-fenton degradation of methylene blue using fe-based metal-organic frameworks. ACS Appl Mater Interfaces 12(8):9292–9299CrossRef

111.

Atta AM et al (2020) Methylene blue catalytic degradation using silver and magnetite nanoparticles functionalized with a poly(ionic liquid) based on quaternized dialkylethanolamine with 2-acrylamido-2-methylpropane sulfonate-co-vinylpyrrolidone. ACS Omega 5(6):2829–2842CrossRef

112.

Pereira L et al (2010) Thermal modification of activated carbon surface chemistry improves its capacity as redox mediator for azo dye reduction. J Hazard Mater 183(1–3):931–939CrossRef

113.

Jeffery AA, Rao SR, Rajamathi M (2017) Preparation of MoS2–reduced graphene oxide (rGO) hybrid paper for catalytic applications by simple exfoliation–costacking. Carbon 112:8–16CrossRef

114.

Alvarez L et al (2010) Immobilized redox mediator on metal-oxides nanoparticles and its catalytic effect in a reductive decolorization process. J Hazard Mater 184(1–3):268–272CrossRef

115.

Jing W et al (2009) Enhanced biodecolorization of azo dyes by electropolymerization-immobilized redox mediator. J Hazard Mater 168(2–3):1098–1104CrossRef

116.

Zhang C et al (2014) Insoluble Fe-humic acid complex as a solid-phase electron mediator for microbial reductive dechlorination. Environ Sci Technol 48(11):6318–6325CrossRef

117.

Cruz-Zavala AS et al (2016) Immobilization of metal–humic acid complexes in anaerobic granular sludge for their application as solid-phase redox mediators in the biotransformation of iopromide in UASB reactors. Biores Technol 207:39–45CrossRef

118.

Zhu Z, Tao L, Li F (2014) 2-Nitrophenol reduction promoted by S. putrefaciens 200 and biogenic ferrous iron: The role of different size-fractions of dissolved organic matter. J Hazardous Mater 279:436–443CrossRef

119.

Zhu Z, Tao L, Li F (2013) Effects of dissolved organic matter on adsorbed Fe (II) reactivity for the reduction of 2-nitrophenol in TiO2 suspensions. Chemosphere 93(1):29–34CrossRef

120.

Khan MN et al (2017) Catalytic activity of cobalt nanoparticles for dye and 4-nitro phenol degradation: a kinetic and mechanistic study. Int J Chem Kinetics 49(6):438–454CrossRef

121.

Palaniselvam T, Aiyappa HB, Kurungot SJJoMC, (2012) An efficient oxygen reduction electrocatalyst from graphene by simultaneously generating pores and nitrogen doped active sites. J Mater Chem 22(45):23799–23805CrossRef

122.

Mobasser S, Firoozi AA (2016) Review of nanotechnology applications in science and engineering. J Civil Eng Urban 6(4):84–93

123.

Sanchez F, Sobolev K (2010) Nanotechnology in concrete–a review. Constr Build Mater 24(11):2060–2071CrossRef

124.

Mondal A, Adhikary B, Mukherjee D (2015) Room-temperature synthesis of air stable cobalt nanoparticles and their use as catalyst for methyl orange dye degradation. Colloids Surf, A 482:248–257CrossRef

125.

Srinivas PR et al (2010) Nanotechnology research: applications in nutritional sciences. J Nutr 140(1):119–124CrossRef

126.

Kung HH, Kung MC (2004) Nanotechnology: applications and potentials for heterogeneous catalysis. Catal Today 97(4):219–224CrossRef

127.

Bhowmik T, Kundu MK, Barman S (2015) Ultra small gold nanoparticles–graphitic carbon nitride composite: an efficient catalyst for ultrafast reduction of 4-nitrophenol and removal of organic dyes from water. RSC Adv 5(48):38760–38773CrossRef

128.

Bharath G et al (2018) Sunlight-Induced photochemical synthesis of Au nanodots on α-Fe 2 O 3@ Reduced graphene oxide nanocomposite and their enhanced heterogeneous catalytic properties. Sci Rep 8(1):1–14CrossRef

129.

Iqbal K et al (2017) A new Ce-doped MgAl-LDH@Au nanocatalyst for highly efficient reductive degradation of organic contaminants. J Mater Chem A 5(14):6716–6724CrossRef

130.

Hanke T et al (2012) Tailoring spatiotemporal light confinement in single plasmonic nanoantennas. Nano Lett 12(2):992–996CrossRef

131.

Noguez C (2007) Surface plasmons on metal nanoparticles: the influence of shape and physical environment. J Phys Chem C 111(10):3806–3819CrossRef

132.

Narasaiah P, Mandal BK, Sarada NC (2017) Biosynthesis of copper oxide nanoparticles from Drypetes sepiaria Leaf extract and their catalytic activity to dye degradation. IOP Conference Series: Materials Sci Eng 263:022012CrossRef

133.

David L, Moldovan BJN (2020) Green synthesis of biogenic silver nanoparticles for efficient catalytic removal of harmful organic dyes. Nanomaterials 10(2):202CrossRef

134.

Begum R et al (2017) Catalytic reduction of 4-nitrophenol using silver nanoparticles-engineered poly (N-isopropylacrylamide-co-acrylamide) hybrid microgels. Appl Organometall Chem 31(2):e3563CrossRef

135.

Wu Y-G et al (2014) Ni/graphene nanostructure and its electron-enhanced catalytic action for hydrogenation reaction of nitrophenol. J Phys Chem C 118(12):6307–6313CrossRef

136.

Zhang M et al (2007) Synthesis, characterization and application of well-defined environmentally responsive polymer brushes on the surface of colloid particles. Polymer 48(7):1989–1997CrossRef

137.

Varadavenkatesan T, Selvaraj R, Vinayagam R (2016) Phyto-synthesis of silver nanoparticles from Mussaenda erythrophylla leaf extract and their application in catalytic degradation of methyl orange dye. J Mol Liq 221:1063–1070CrossRef

138.

Naseem K et al (2018) Removal of Congo red dye from aqueous medium by its catalytic reduction using sodium borohydride in the presence of various inorganic nano-catalysts: A review. J Clean Prod 187:296–307CrossRef

139.

Joseph S (2015) Mathew BJMS Facile synthesis of silver nanoparticles and their application in dye degradation. Mater Sci Eng: C 195:90–97CrossRef

140.

Ţǎlu Ş et al (2015) Surface morphology of titanium nitride thin films synthesized by DC reactive magnetron sputtering. Mater Sci-Pol 33(1):137–143CrossRef

141.

Saha J et al (2017) A novel green synthesis of silver nanoparticles and their catalytic action in reduction of Methylene Blue dye. Sustainable Environ Res 27(5):245–250CrossRef

142.

Farooqi ZH et al (2014) Effect of crosslinker feed content on catalaytic activity of silver nanoparticles fabricated in multiresponsive microgels. Korean J Chem Eng 31(9):1674–1680CrossRef

143.

Farooqi ZH et al. (2014) Cobalt and nickel nanoparticles fabricated p (NIPAM-co-MAA) microgels for catalytic applications. e-Polymers, 14(5): 313–321.

144.

Yang D et al (2018) Poly (N-acryloylglycinamide) microgels as nanocatalyst platform. Polym Chem 9(4):517–524CrossRef

145.

Farooqi ZH et al (2015) Fabrication of silver nanoparticles in poly (N-isopropylacrylamide-co-allylacetic acid) microgels for catalytic reduction of nitroarenes. Turk J Chem 39(3):576–588CrossRef

146.

Ashraf S et al (2018) Synthesis and characterization of pH-responsive organic-inorganic hybrid material with excellent catalytic activity. J Inorg Organomet Polym Mater 28(5):1872–1884CrossRef

147.

Begum R et al (2016) Simultaneous catalytic reduction of nitroarenes using silver nanoparticles fabricated in poly (N-isopropylacrylamide-acrylic acid-acrylamide) microgels. Colloids Surf, A 511:17–26CrossRef

148.

Nguyen T-N-P, Chen P-C, Huang C (2018) Nitrate removal and extracellular polymeric substances of autohydrogenotrophic bacteria under various pH and hydrogen flow rates. J Environ Sci 63:50–57CrossRef

149.

Satapathy SS et al (2017) Thermo-responsive PNIPAM-metal hybrids: An efficient nanocatalyst for the reduction of 4-nitrophenol. Appl Surf Sci 420:753–763CrossRef

150.

Shah LA et al (2016) Synthesis of sensitive hybrid polymer microgels for catalytic reduction of organic pollutants. J Environ Chem Eng 4(3):3492–3497CrossRef

151.

Farooqi ZH et al (2015) Effect of acrylic acid feed contents of microgels on catalytic activity of silver nanoparticles fabricated hybrid microgels. Turkish J Chem 39(1):96–107CrossRef

152.

Kazeminava F, Arsalani N, Akbari A (2018) POSS nanocrosslinked poly (ethylene glycol) hydrogel as hybrid material support for silver nanocatalyst. Appl Organometall Chem 32(6):e4359CrossRef

153.

Gangula A, Podila R, Karanam L, Janardhana C, Rao AM (2011) Catalytic reduction of 4-nitrophenol using biogenic gold and silver nanoparticles derived from Breynia rhamnoides. Langmuir 27(24):15268–15274CrossRef

154.

Zayed MF, Eisa WH (2014) Phoenix dactylifera L leaf extract phytosynthesized gold nanoparticles; controlled synthesis and catalytic activity. Spectrochim Acta Part A Mole Biomole Spectrosc 121:238–244CrossRef

155.

Guria MK, Majumdar M, Bhattacharyya M (2016) Green synthesis of protein capped nano-gold particle: An excellent recyclable nano-catalyst for the reduction of nitro-aromatic pollutants at higher concentration. J Mol Liq 222:549–557CrossRef

156.

Sahiner N et al (2010) New catalytic route: Hydrogels as templates and reactors for in situ Ni nanoparticle synthesis and usage in the reduction of 2- and 4-nitrophenols. Appl Catal A 385(1):201–207CrossRef

157.

Nimita Jebaranjitham J et al (2019) Fabrication of amine functionalized graphene oxide – AgNPs nanocomposite with improved dispersibility for reduction of 4-nitrophenol. Compos B Eng 171:302–309CrossRef

158.

Alayoglu S, Eichhorn B (2008) Rh− Pt bimetallic catalysts: synthesis, characterization, and catalysis of core− shell, alloy, and monometallic nanoparticles. J Am Chem Soc 130(51):17479–17486CrossRef

159.

Sinfelt JH (1973) Supported “bimetallic cluster” catalysts. J Catal 29(2):308–315CrossRef

160.

Sinfelt J, Cusumano J (1983) Bimetallic catalysts. discoveries, concepts and applications/JH Sinfelt.

161.

Ghosh SK et al (2004) Bimetallic Pt–Ni nanoparticles can catalyze reduction of aromatic nitro compounds by sodium borohydride in aqueous solution. Appl Catal A 268(1):61–66CrossRef

162.

Ma Y, Wu X, Zhang G (2017) Core-shell Ag@Pt nanoparticles supported on sepiolite nanofibers for the catalytic reduction of nitrophenols in water: Enhanced catalytic performance and DFT study. Appl Catal B 205:262–270CrossRef

163.

Lu Y et al (2010) In situ growth of catalytic active Au− Pt bimetallic nanorods in thermoresponsive core− shell microgels. ACS Nano 4(12):7078–7086CrossRef

164.

Wu T et al (2013) Fabrication of graphene oxide decorated with Au–Ag alloy nanoparticles and its superior catalytic performance for the reduction of 4-nitrophenol. J Mater Chem A 1(25):7384–7390CrossRef

165.

Xu Z et al (2019) Catalytic reduction of 4-nitrophenol over graphene supported Cu@Ni bimetallic nanowires. Mater Chem Phys 227:64–71CrossRef

166.

Gao X et al (2019) Facile synthesis of PdNiP/Reduced graphene oxide nanocomposites for catalytic reduction of 4-nitrophenol. Mater Chem Phys 222:391–397CrossRef

167.

Begum R et al 2017 Catalytic reduction of 4‐nitrophenol using silver nanoparticles‐engineered poly (N‐isopropylacrylamide‐co‐acrylamide) hybrid microgels. 31(2): e3563.

168.

Ţǎlu Ş et al (2015) Surface Morphol Titanium Nitride Thin Films Synthesized by DC Reactive Magnetron Sputtering 33(1):137–143

169.

Farooqi ZH et al (2014) Cobalt and nickel nanoparticles fabricated p (NIPAM-co-MAA). Microgels Catalytic Appl 14(5):313–321

170.

Farooqi ZH, et al (2015) Fabrication of silver nanoparticles in poly (N-isopropylacrylamide-co-allylacetic acid) microgels for catalytic reduction of nitroarenes. 39(3): 576–588.

171.

Ashraf S, et al (2018) Synthesis and characterization of pH-responsive organic–inorganic hybrid material with excellent catalytic activity, 28(5): 1872–1884.

172.

Begum R et al (2016) Simultaneous catalytic reduction of nitroarenes using silver nanoparticles fabricated in poly (N-isopropylacrylamide-acrylic acid-acrylamide) microgels. 511: 17–26.

173.

Begum R et al (2018) Engineering of responsive polymer based nano-reactors for facile mass transport and enhanced catalytic degradation of 4-nitrophenol. 72:43–52

174.

Farooqi ZH et al (2015) Effect of acrylic acid feed contents of microgels on catalytic activity of silver nanoparticles fabricated hybrid microgels. 39(1):96–107

175.

Khan SR, et al (2013) Synthesis, characterization, and silver nanoparticles fabrication in N-isopropylacrylamide-based polymer microgels for rapid degradation of p-nitrophenol. 34(10): 1324–1333.

176.

Dai Y, Li, Y, Wang, SJJoC (2015) ABC triblock copolymer-stabilized gold nanoparticles for catalytic reduction of nitrophenol. 329: 425–430.

177.

Kuroda K, Ishida T, Haruta, MJJoMCAC (2009) Reduction of nitrophenol to aminophenol over Au nanoparticles deposited on PMMA. 298(1–2): 7–11.

178.

Pozun ZD et al (2013) A systematic investigation of p-nitrophenol reduction by bimetallic dendrimer encapsulated nanoparticles 117(15):7598–7604

179.

Esumi K, Isono R, Yoshimura TJL (2004) Preparation of PAMAM− and PPI− metal (silver, platinum, and palladium) nanocomposites and their catalytic activities for reduction of 4-nitrophenol. 20(1): 237–243.

180.

Ajmal M, Farooqi, ZH, Siddiq MJKJoCE (2013) Silver nanoparticles containing hybrid polymer microgels with tunable surface plasmon resonance and catalytic activity. 30(11): 2030–2036.

181.

Zhai L et al (2018) Synthesis, characterization, and antibacterial property of eco-friendly Ag/cellulose nanocomposite film. 67(7): 420–426.

182.

ur Rehman S, et al (2015) Cationic microgels embedding metal nanoparticles in the reduction of dyes and nitro-phenols. 265: 201–209.

183.

Yao T, et al (2013) Preparation of yolk–shell Fe x O y/Pd@ mesoporous SiO 2 composites with high stability and their application in catalytic reduction of 4-nitrophenol. 5(13): 5896–5904.

184.

Singh J, Dhaliwal AJJoP, Environment t (2021) Effective removal of methylene blue dye using silver nanoparticles containing grafted polymer of guar gum/acrylic acid as novel adsorbent. 29(1): 71–88.

185.

Ezhilarasu D, Murugan EJJC (2012) Sci, Synthesis, characterization and catalytic activity of ruthenium and silver immobilized heterogeneous nanoparticle catalysts 2:61–75

186.

Zeng T et al (2013) situ growth of gold nanoparticles onto polydopamine-encapsulated magnetic microspheres for catalytic reduction of nitrobenzene 134:26–33

187.

Rai RK et al (2014) Room-temperature chemoselective reduction of nitro groups using non-noble metal nanocatalysts in water 53(6):2904–2909

188.

Du X, Yao L, He JJCAEJ (2012) One‐pot fabrication of noble‐metal nanoparticles that are encapsulated in hollow silica nanospheres: dual roles of poly (acrylic acid). 18(25): 7878–7885.

189.

Seo E et al (2013) Double hydrophilic block copolymer templated Au nanoparticles with enhanced catalytic activity toward nitroarene reduction 117(22):11686–11693

190.

Naseem K, Begum, R, Farooqi ZHJPC (2018) Platinum nanoparticles fabricated multiresponsive microgel composites: synthesis, characterization, and applications. 39(7): 2167–2180.

191.

Naseem K et al (2017) Catalytic reduction of 2-nitroaniline: a review. Environ Sci Pollut Res 24(7):6446–6460CrossRef

192.

Mohanta J, Satapathy S, Si SJC (2016) Porous silica‐coated gold nanorods: a highly active catalyst for the reduction of 4‐nitrophenol. 17(3): 364–368.

193.

Nasrollahzadeh M et al (2016) In situ green synthesis of Ag nanoparticles on graphene oxide/TiO2 nanocomposite and their catalytic activity for the reduction of 4-nitrophenol, congo red and methylene blue. Ceram Int 42(7):8587–8596CrossRef

194.

Chen L-H et al (2020) Photocatalytic properties of graphene/gold and graphene oxide/gold nanocomposites synthesized by pulsed laser induced photolysis 10(10):1985

195.

Mondal B et al (2016) Graphene induced porphyrin nano-aggregates for efficient electron transfer and photocurrent generation 4(25):6027–6036

196.

Bharath G, et al (2021) Synthesis of TiO2/RGO with plasmonic Ag nanoparticles for highly efficient photoelectrocatalytic reduction of CO2 to methanol toward the removal of an organic pollutant from the atmosphere. 281: 116990.

197.

Sravanthi K, Ayodhya D, Swamy PYJMSfET (2019) Green synthesis, characterization and catalytic activity of 4-nitrophenol reduction and formation of benzimidazoles using bentonite supported zero valent iron nanoparticles. 2(2): p. 298–307.

198.

Shi L et al (2012) High catalytic performance of gold nanoparticle–gelatin mesoporous composite thin films. 22(39): 21117–21124.

199.

Dauthal P, Mukhopadhyay MJI, ec research (2012) Prunus domestica fruit extract-mediated synthesis of gold nanoparticles and its catalytic activity for 4-nitrophenol reduction. 51(40): 13014–13020.

200.

Zhang W et al (2015) Liquid metal/metal oxide frameworks with incorporated Ga2O3 for photocatalysis. ACS Appl Mater Interfaces 7(3):1943–1948CrossRef

201.

Hatamifard A, Nasrollahzadeh M, Lipkowski J (2015) Green synthesis of a natrolite zeolite/palladium nanocomposite and its application as a reusable catalyst for the reduction of organic dyes in a very short time. RSC Adv 5(111):91372–91381CrossRef

202.

Jia Z et al (2014) Catalytic bubble-free hydrogenation reduction of azo dye by porous membranes loaded with palladium nanoparticles. J Environ Sci 26(2):478–482CrossRef

203.

Rajesh R, Kumar SS, Venkatesan RJNJoC (2014) Efficient degradation of azo dyes using Ag and Au nanoparticles stabilized on graphene oxide functionalized with PAMAM dendrimers. 38(4): 1551–1558.

204.

Wu T, et al (2013) Fabrication of graphene oxide decorated with Au–Ag alloy nanoparticles and its superior catalytic performance for the reduction of 4-nitrophenol. 1(25): 7384–7390.

205.

Din MI et al (2020) Nanocatalytic assemblies for catalytic reduction of nitrophenols: a critical review 50(4):322–338

206.

Wunder S, et al (2010) Kinetic analysis of catalytic reduction of 4-nitrophenol by metallic nanoparticles immobilized in spherical polyelectrolyte brushes. 114(19): 8814–8820.

207.

Abay AK, Chen X, Kuo D-HJNJoC (2017) Highly efficient noble metal free copper nickel oxysulfide nanoparticles for catalytic reduction of 4-nitrophenol, methyl blue, and rhodamine-B organic pollutants. 41(13): 5628–5638.

208.

Abay AK, Chen X, Kuo D-H (2017) Highly efficient noble metal free copper nickel oxysulfide nanoparticles for catalytic reduction of 4-nitrophenol, methyl blue, and rhodamine-B organic pollutants. New J Chem 41(13):5628–5638CrossRef

209.

Akhtar K et al (2020) Lignocellulosic biomass supported metal nanoparticles for the catalytic reduction of organic pollutants. Environ Sci Pollut Res 27(1):823–836CrossRef

210.

Ahsan MA et al (2019) (2019) Ultrafast catalytic reduction of environmental pollutants in water via MOF-derived magnetic Ni and Cu nanoparticles encapsulated in porous carbon. Appl Surface Sci 497:143608CrossRef

211.

Gangapuram BR et al (2018) Microwave assisted rapid green synthesis of gold nanoparticles using Annona squamosa L peel extract for the efficient catalytic reduction of organic pollutants 1167:305–315

212.

Bordbar M, Mortazavimanesh NJES, Research P (2017) Green synthesis of Pd/walnut shell nanocomposite using Equisetum arvense L. leaf extract and its application for the reduction of 4-nitrophenol and organic dyes in a very short time. 24(4): 4093–4104.

213.

Gangarapu M et al (2017) A high-performance catalytic and recyclability of phyto-synthesized silver nanoparticles embedded in natural polymer. J Cluster Sci 28(6):3127–3138CrossRef

214.

Khazaei M, et al (2017) Highly efficient reusable Pd nanoparticles based on eggshell: green synthesis, characterization and their application in catalytic reduction of variety of organic dyes and ligand-free oxidative hydroxylation of phenylboronic acid at room temperature. 73(38): 5613–5623.

215.

Kundu S et al (2017) Shape-selective catalysis and surface enhanced Raman scattering studies using Ag nanocubes, nanospheres and aggregated anisotropic nanostructures. J Colloid Interface Sci 498:248–262CrossRef

216.

Omidvar A et al (2017) Fabrication, characterization and application of GO/Fe3O4/Pd nanocomposite as a magnetically separable and reusable catalyst for the reduction of organic dyes. Chem Eng Res Des 121:339–347CrossRef

217.

Veisi H, S Azizi, Mohammadi PJJocp (2018) Green synthesis of the silver nanoparticles mediated by Thymbra spicata extract and its application as a heterogeneous and recyclable nanocatalyst for catalytic reduction of a variety of dyes in water. 170: 1536–1543.

218.

Shah D, Kaur H (2014) Resin-trapped gold nanoparticles: An efficient catalyst for reduction of nitro compounds and Suzuki-Miyaura coupling. J Mol Catal A: Chem 381:70–76CrossRef

219.

Kalbasi RJ, Nourbakhsh AA, Babaknezhad F (2011) Synthesis and characterization of Ni nanoparticles-polyvinylamine/SBA-15 catalyst for simple reduction of aromatic nitro compounds. Catal Commun 12(11):955–960CrossRef

220.

Layek K et al (2012) Gold nanoparticles stabilized on nanocrystalline magnesium oxide as an active catalyst for reduction of nitroarenes in aqueous medium at room temperature. Green Chem 14(11):3164–3174CrossRef

221.

Saha S, et al (2010) Photochemical green synthesis of calcium-alginate-stabilized Ag and Au nanoparticles and their catalytic application to 4-nitrophenol reduction. 26(4): 2885–2893.

222.

Wang Z et al (2014) Facile synthesis of well-dispersed Pd–graphene nanohybrids and their catalytic properties in 4-nitrophenol reduction. RSC Adv 4(26):13644–13651CrossRef

223.

Wang X et al (2014) Facile synthesis of Au nanoparticles supported on polyphosphazene functionalized carbon nanotubes for catalytic reduction of 4-nitrophenol. J Mater Sci 49(14):5056–5065. https://doi.org/10.1007/s10853-014-8212-5CrossRef

224.

Choi Y et al (2011) Hybrid gold nanoparticle-reduced graphene oxide nanosheets as active catalysts for highly efficient reduction of nitroarenes. J Mater Chem 21(39):15431–15436CrossRef

225.

Dong Z et al (2014) Silver nanoparticles immobilized on fibrous nano-silica as highly efficient and recyclable heterogeneous catalyst for reduction of 4-nitrophenol and 2-nitroaniline. Appl Catal B 158:129–135CrossRef

226.

Gao J et al (2015) Plasma-assisted synthesis of Ag nanoparticles immobilized in mesoporous cellular foams and their catalytic properties for 4-nitrophenol reduction. Microporous Mesoporous Mater 207:149–155CrossRef

227.

Sahiner N (2013) Soft and flexible hydrogel templates of different sizes and various functionalities for metal nanoparticle preparation and their use in catalysis. Prog Polym Sci 38(9):1329–1356CrossRef

228.

Islam M et al (2010) Synthesis, characterization and catalytic activities of a reusable polymer-anchored palladium (II) complex: effective catalytic hydrogenation of various organic substrates. Transition Met Chem 35(4):427–435CrossRef

229.

Li J, Liu C-Y, Liu Y (2012) Au/graphene hydrogel: synthesis, characterization and its use for catalytic reduction of 4-nitrophenol. J Mater Chem 22(17):8426–8430CrossRef

230.

Xie M et al (2013) Pt nanoparticles supported on carbon coated magnetic microparticles: an efficient recyclable catalyst for hydrogenation of aromatic nitro-compounds. RSC Adv 3(26):10329–10334CrossRef

231.

Yang H et al (2014) Imidazolium ionic liquid-modified fibrous silica microspheres loaded with gold nanoparticles and their enhanced catalytic activity and reusability for the reduction of 4-nitrophenol. J Mater Chem A 2(30):12060–12067CrossRef

232.

Ghosh BK et al (2015) Preparation of Cu nanoparticle loaded SBA-15 and their excellent catalytic activity in reduction of variety of dyes. Powder Technol 269:371–378CrossRef

233.

Dong Z et al (2014) Silver nanoparticles immobilized on fibrous nano-silica as highly efficient and recyclable heterogeneous catalyst for reduction of 4-nitrophenol and 2-nitroaniline. Appl Catal B 158–159:129–135CrossRef

234.

Chandra A, Singh M (2018) Biosynthesis of amino acid functionalized silver nanoparticles for potential catalytic and oxygen sensing applications. Inorganic Chem Front 5(1):233–257CrossRef

235.

Rauf MA et al (2010) Photocatalytic degradation of methylene blue using a mixed catalyst and product analysis by LC/MS. Chem Eng J 157(2):373–378CrossRef

236.

Laoufi I et al (2011) Size and catalytic activity of supported gold nanoparticles: an in operando study during CO oxidation. J Phys Chem C 115(11):4673–4679CrossRef

237.

Hamity M et al (2008) UV–vis photodegradation of dyes in the presence of colloidal Q-CdS. J Photochem Photobiol, A 200(2):445–450CrossRef

238.

Chandra A, Singh MJICF (2018) Biosynthesis of amino acid functionalized silver nanoparticles for potential catalytic and oxygen sensing applications. 5(1): 233–257.

239.

Saad A, et al (2016) Ligand-modified mesoporous silica SBA-15/silver hybrids for the catalyzed reduction of methylene blue. 6(62): 57672–57682.

240.

Recio-Sánchez G et al (2019) Assessing the effectiveness of green synthetized silver nanoparticles with Cryptocarya alba extracts for remotion of the organic pollutant methylene blue dye. Environ Sci Pollut Res 26(15):15115–15123CrossRef

241.

Kamali M, Samari F, Sedaghati F (2019) Low-temperature phyto-synthesis of copper oxide nanosheets: Its catalytic effect and application for colorimetric sensing. Mater Sci Eng: C 103:109744CrossRef

242.

Kushwah M et al (2019) Enhanced catalytic activity of chemically synthesized Au/Ag/Cu trimetallic nanoparticles. Mater Res Express 6(9):095013CrossRef

243.

Gangapuram BR et al (2018) Microwave assisted rapid green synthesis of gold nanoparticles using Annona squamosa L peel extract for the efficient catalytic reduction of organic pollutants. J Mol Struct 1167:305–315CrossRef

244.

Bordbar M, Mortazavimanesh N (2017) Green synthesis of Pd/walnut shell nanocomposite using Equisetum arvense L. leaf extract and its application for the reduction of 4-nitrophenol and organic dyes in a very short time. Environ Sci Pollution Res 24(4):4093–4104CrossRef

245.

Hasan Z et al (2016) Catalytic decoloration of commercial azo dyes by copper-carbon composites derived from metal organic frameworks. J Alloy Compd 689:625–631CrossRef

246.

Issaabadi Z, Nasrollahzadeh M, Sajadi SM (2017) Green synthesis of the copper nanoparticles supported on bentonite and investigation of its catalytic activity. J Clean Prod 142:3584–3591CrossRef

247.

Khodadadi B et al (2017) Green synthesis of Ag nanoparticles/clinoptilolite using vaccinium macrocarpon fruit extract and its excellent catalytic activity for reduction of organic dyes. J Alloy Compd 719:82–88CrossRef

248.

Momeni SS, Nasrollahzadeh M, Rustaiyan A (2016) Green synthesis of the Cu/ZnO nanoparticles mediated by Euphorbia prolifera leaf extract and investigation of their catalytic activity. J Colloid Interface Sci 472:173–179CrossRef

249.

Yeganeh-Faal A, et al (2017) Green synthesis of the Ag/ZnO nanocomposite using <i>Valeriana officinalis L.</i> root extract: application as a reusable catalyst for the reduction of organic dyes in a very short time. IET Nanobiotechnology 11: 669–676.

250.

Ke R et al (2016) Facile synthesis of hexagonal Ni0.85Se nanosheet and its application as adsorbent and catalyst to dyes. Chem Phys Lett 651:103–108CrossRef

251.

Gan Z et al (2013) Controlled synthesis of Au-loaded Fe 3 O 4@ C composite microspheres with superior SERS detection and catalytic degradation abilities for organic dyes. Dalton Trans 42(24):8597–8605CrossRef

252.

Zhang Y et al (2014) Hierarchical architectures of monodisperse porous Cu microspheres: synthesis, growth mechanism, high-efficiency and recyclable catalytic performance. J Mater Chem A 2(30):11966–11973CrossRef

253.

Yang X et al (2014) Highly efficient reusable catalyst based on silicon nanowire arrays decorated with copper nanoparticles. J Mater Chem A 2(24):9040–9047CrossRef

254.

Ganapuram BR et al (2015) Catalytic reduction of methylene blue and Congo red dyes using green synthesized gold nanoparticles capped by salmalia malabarica gum. Int Nano Lett 5(4):215–222CrossRef

255.

Indana MK et al (2016) A novel green synthesis and characterization of silver nanoparticles using gum tragacanth and evaluation of their potential catalytic reduction activities with methylene blue and Congo red dyes. J Analy Sci Technol 7(1):19CrossRef

256.

Jiang Z-J, Liu C-Y, Sun L-W (2005) Catalytic properties of silver nanoparticles supported on silica spheres. J Phys Chem B 109(5):1730–1735CrossRef

257.

Dutt S, et al (2015) Gold core–polyaniline shell composite nanowires as a substrate for surface enhanced Raman scattering and catalyst for dye reduction. 39(2): 902–908.

258.

Ai L, Zeng C, Wang QJCC (2011) One-step solvothermal synthesis of Ag-Fe3O4 composite as a magnetically recyclable catalyst for reduction of Rhodamine B. Catal Commun 14(1):68–73CrossRef

259.

Atarod M, Nasrollahzadeh M, Sajadi SM (2016) Euphorbia heterophylla leaf extract mediated green synthesis of Ag/TiO2 nanocomposite and investigation of its excellent catalytic activity for reduction of variety of dyes in water. J Colloid Interface Sci 462:272–279CrossRef

260.

Deng Z et al (2012) Synthesis of PS/Ag nanocomposite spheres with catalytic and antibacterial activities. ACS Appl Mater Interfaces 4(10):5625–5632CrossRef

261.

Zhang B, et al (2012) One-pot interfacial synthesis of Au nanoparticles and Au–polyaniline nanocomposites for catalytic applications. 14(5): 1542–1544.

262.

Xuan S et al (2009) Preparation, characterization, and catalytic activity of core/shell Fe3O4@ polyaniline@ Au nanocomposites. Langmuir 25(19):11835–11843CrossRef

263.

Zhang P et al (2014) A one-step green route to synthesize copper nanocrystals and their applications in catalysis and surface enhanced Raman scattering. Nanoscale 6(10):5343–5350CrossRef

264.

Kalwar NH et al (2013) Fabrication of small l-threonine capped nickel nanoparticles and their catalytic application. Appl Catal A 453:54–59CrossRef

265.

Chen M et al (2014) Fast catalytic reduction of an azo dye by recoverable and reusable Fe 3 O 4@ PANI@ Au magnetic composites. New J Chem 38(9):4566–4573CrossRef

266.

Rostami-Vartooni A, Nasrollahzadeh M, Alizadeh M (2016) Green synthesis of perlite supported silver nanoparticles using Hamamelis virginiana leaf extract and investigation of its catalytic activity for the reduction of 4-nitrophenol and Congo red. J Alloy Compd 680:309–314CrossRef

267.

Zheng Y, Wang A (2012) Ag nanoparticle-entrapped hydrogel as promising material for catalytic reduction of organic dyes. J Mater Chem 22(32):16552–16559CrossRef

268.

Rajesh R, Kumar SS, Venkatesan R (2014) Efficient degradation of azo dyes using Ag and Au nanoparticles stabilized on graphene oxide functionalized with PAMAM dendrimers. New J Chem 38(4):1551–1558CrossRef

269.

Rajalakshmi S et al (2017) Enhanced photocatalytic activity of metal oxides/β-cyclodextrin nanocomposites for decoloration of Rhodamine B dye under solar light irradiation 7(1):115–127

270.

Zhang B et al (2012) One-pot interfacial synthesis of Au nanoparticles and Au–polyaniline nanocomposites for catalytic applications. CrystEngComm 14(5):1542–1544CrossRef

271.

Khan Z et al (2017) Cationic surfactant assisted morphology of Ag@Cu, and their catalytic reductive degradation of Rhodamine B. J Mol Liq 248:1096–1108CrossRef

272.

Du S, et al (2017) Polydopamine-coated Fe3O4 nanoparticles as synergistic redox mediators for catalytic reduction of azo dyes. 12(03): 1750037.

273.

Sajjadi M, Nasrollahzadeh M, Sajadi SM (2017) Green synthesis of Ag/Fe3O4 nanocomposite using Euphorbia peplus Linn leaf extract and evaluation of its catalytic activity. J Colloid Interface Sci 497:1–13CrossRef

274.

Nasrollahzadeh M et al (2018) Green synthesis of the Cu/sodium borosilicate nanocomposite and investigation of its catalytic activity. J Alloy Compd 763:1024–1034CrossRef

275.

Khazaei M et al (2017) Highly efficient reusable Pd nanoparticles based on eggshell: Green synthesis, characterization and their application in catalytic reduction of variety of organic dyes and ligand-free oxidative hydroxylation of phenylboronic acid at room temperature. Tetrahedron 73(38):5613–5623CrossRef

276.

Lajevardi A et al (2019) Green synthesis of MOF@Ag nanocomposites for catalytic reduction of methylene blue. J Mol Liq 276:371–378CrossRef

277.

Ji X et al (2018) A monodisperse anionic silver nanoparticles colloid: Its selective adsorption and excellent plasmon-induced photodegradation of Methylene Blue. J Colloid Interface Sci 523:98–109CrossRef

278.

Tian Q et al (2017) Monodisperse raspberry-like multihollow polymer/Ag nanocomposite microspheres for rapid catalytic degradation of methylene blue. J Colloid Interface Sci 491:294–304CrossRef

279.

Xie Y et al (2014) Highly regenerable mussel-inspired Fe3O4@Polydopamine-Ag core-shell microspheres as catalyst and adsorbent for methylene blue removal. ACS Appl Mater Interfaces 6(11):8845–8852CrossRef

280.

Xu Y et al (2020) Remarkably catalytic activity in reduction of 4-nitrophenol and methylene blue by Fe3O4@COF supported noble metal nanoparticles. Appl Catalysis B: Environmental 260:118142CrossRef

281.

Jia Z et al (2019) Cotton fiber-biotemplated synthesis of Ag fibers: Catalytic reduction for 4-nitrophenol and SERS application. Solid State Sci 94:120–126CrossRef

282.

Li H et al (2019) Preparation of silver-nanoparticle-loaded magnetic biochar/poly(dopamine) composite as catalyst for reduction of organic dyes. J Colloid Interface Sci 555:460–469CrossRef

283.

Li Z-X et al (2018) Metal-directed assembly of five 4-connected mofs: one-pot syntheses of MOF-Derived MxSy@C composites for photocatalytic degradation and supercapacitors. Cryst Growth Des 18(2):979–992CrossRef

284.

Sharma K, Vyas RK, Dalai AK (2017) Thermodynamic and kinetic studies of methylene blue degradation using reactive adsorption and its comparison with adsorption. J Chem Eng Data 62(11):3651–3662CrossRef

285.

Wei Q et al (2016) In situ formation of gold nanoparticles on magnetic halloysite nanotubes via polydopamine chemistry for highly effective and recyclable catalysis. RSC Adv 6(35):29245–29253CrossRef

286.

Sahiner N, Sagbas S, Aktas N (2015) Very fast catalytic reduction of 4-nitrophenol, methylene blue and eosin Y in natural waters using green chemistry: p(tannic acid)–Cu ionic liquid composites. RSC Adv 5(24):18183–18195CrossRef

287.

Liang Y et al (2017) Decorating of Ag and CuO on Cu nanoparticles for enhanced high catalytic activity to the degradation of organic pollutants. Langmuir 33(31):7606–7614CrossRef

288.

Cui K et al (2018) Regenerable urchin-like Fe3O4@PDA-Ag hollow microspheres as catalyst and adsorbent for enhanced removal of organic dyes. J Hazard Mater 350:66–75CrossRef

289.

Sahoo PK et al (2018) Freeze-casting of multifunctional cellular 3d-graphene/ag nanocomposites: synergistically affect supercapacitor, catalytic, and antibacterial properties. ACS Sustainable Chem Eng 6(6):7475–7487CrossRef

290.

Luo J et al (2015) Tannic acid functionalized graphene hydrogel for entrapping gold nanoparticles with high catalytic performance toward dye reduction. J Hazard Mater 300:615–623CrossRef

291.

Sohni S et al (2018) Room temperature preparation of lignocellulosic biomass supported heterostructure (Cu+Co@OPF) as highly efficient multifunctional nanocatalyst using wetness co-impregnation. Colloids Surf, A 549:184–195CrossRef

292.

Veisi H et al (2019) Silver nanoparticle-decorated on tannic acid-modified magnetite nanoparticles (Fe3O4@TA/Ag) for highly active catalytic reduction of 4-nitrophenol, Rhodamine B and Methylene blue. Mater Sci Eng, C 100:445–452CrossRef

293.

Veisi H et al (2019) Silver nanoparticles decorated on thiol-modified magnetite nanoparticles (Fe3O4/SiO2-Pr-S-Ag) as a recyclable nanocatalyst for degradation of organic dyes. Mater Sci Eng, C 97:624–631CrossRef

294.

Atta AM et al (2019) Hybrid ionic silver and magnetite microgels nanocomposites for efficient removal of methylene blue. Molecules 24(21):3867CrossRef

295.

Emam HE, Ahmed HBJIjobm (2019) Comparative study between homo-metallic hetero-metallic nanostructures based agar in catalytic degradation of dyes. Int J Biol Macromole 138:450–461CrossRef

296.

de Jesús Ruíz-Baltazar Á et al (2019) Eco-friendly synthesis of Fe3O4 nanoparticles: evaluation of their catalytic activity in methylene blue degradation by kinetic adsorption models. Results in Phys 12:989–995CrossRef

297.

Singh J, Dhaliwal AJJoP, (2021) Environment, effective removal of methylene blue dye using silver nanoparticles containing grafted polymer of Guar Gum/Acrylic Acid as Novel Adsorbent. J Polym Environ, 29(1): 71–88.

298.

Nasrollahzadeh M, Atarod M, Sajadi SM (2016) Green synthesis of the Cu/Fe3O4 nanoparticles using Morinda morindoides leaf aqueous extract: a highly efficient magnetically separable catalyst for the reduction of organic dyes in aqueous medium at room temperature. Appl Surf Sci 364:636–644CrossRef

299.

Zheng Y, Wang, AJJoMC (2012) Ag nanoparticle-entrapped hydrogel as promising material for catalytic reduction of organic dyes. 22(32): 16552–16559.

300.

Chen M, et al (2014) Fast catalytic reduction of an azo dye by recoverable and reusable Fe 3 O 4@ PANI@ Au magnetic composites. 38(9): 4566–4573.

301.

Wang W et al (2014) Au nanoparticles decorated Kapok fiber by a facile noncovalent approach for efficient catalytic decoloration of Congo Red and hydrogen production. Chem Eng J 237:336–343CrossRef

302.

Kamal T, Khan SB, Asiri AMJC (2016) Synthesis of zero-valent Cu nanoparticles in the chitosan coating layer on cellulose microfibers: evaluation of azo dyes catalytic reduction 23(3):1911–1923

303.

Kalwar NH et al (2013) Fabrication of small l-threonine capped nickel nanoparticles and their catalytic application 453:54–59

304.

Ansari TM et al (2019) Synthesis and characterization of magnetic poly (acrylic acid) hydrogel fabricated with cobalt nanoparticles for adsorption and catalytic applications. J Iran Chem Soc 16(12):2765–2776CrossRef

305.

Azzam EM et al (2019) Enhancement the photocatalytic degradation of methylene blue dye using fabricated CNTs/TiO2/AgNPs/Surfactant nanocomposites. J Water Process Eng 28:311–321CrossRef

306.

Das R et al (2019) Silver decorated magnetic nanocomposite (Fe3O4@ PPy-MAA/Ag) as highly active catalyst towards reduction of 4-nitrophenol and toxic organic dyes. Appl Catal B 244:546–558CrossRef

307.

Ding W et al (2019) Bovine serum albumin assisted synthesis of Ag/Ag2O/ZnO photocatalyst with enhanced photocatalytic activity under visible light. Colloids Surf, A 568:131–140CrossRef

308.

Hu Y et al (2018) Combining batch technique with theoretical calculation studies to analyze the highly efficient enrichment of U (VI) and Eu (III) on magnetic MnFe2O4 nanocubes. Chem Eng J 349:347–357CrossRef

309.

Li L, et al (2019) Functionalization of carbon nanomaterials by means of phytic acid for uranium enrichment. Sci Total Environ, 694: 133697.

310.

Marković M, et al. Supplementary material for the article: Marković M, Marinović S, Mudrinić T, Ajduković M, Jović-Jovičić N, Mojović Z, Orlić J, Milutinović-Nikolić A, Banković, P. Co (II) Impregnated Al (III)-Pillared Montmorillonite–Synthesis, Characterization and Catalytic Properties in Oxone® Activation for Dye Degradation. Applied Clay Science 2019, 182. 10.1016/j. clay. 2019.105276.

311.

Wang X, et al (2019) Synthesis of novel nanomaterials and their application in efficient removal of radionuclides. Sci China Chem 62(8): 933–967.

312.

Mohamed R et al (2013) Nano Cu Metal Doped on TiO2–SiO2 nanoparticle catalysts in photocatalytic degradation of direct blue dye. J Nanosci Nanotechnol 13(7):4975–4980CrossRef

313.

Choi J et al (2017) Preparation and characterization of graphene oxide supported Cu, Cu2O, and CuO nanocomposites and their high photocatalytic activity for organic dye molecule. Curr Appl Phys 17(2):137–145CrossRef

314.

Edla R et al (2015) Highly photo-catalytically active hierarchical 3D porous/urchin nanostructured Co3O4 coating synthesized by pulsed laser deposition. Appl Catal B 166:475–484CrossRef

315.

Han J et al (2016) Catalytic properties of CuMgAlO catalyst and degradation mechanism in CWPO of methyl orange. Appl Catal A 527:72–80CrossRef

316.

Lai X et al (2019) Rapid microwave-assisted bio-synthesized silver/Dandelion catalyst with superior catalytic performance for dyes degradation. J Hazard Mater 371:506–512CrossRef

317.

Zhang C et al (2021) Catalytic mechanism and pathways of 1, 2-dichloropropane oxidation over LaMnO3 perovskite: an experimental and DFT study. J Hazard Mater 402:123473CrossRef

318.

Cheriyan S et al (2018) Doping effect on monolayer MoS2 for visible light dye degradation-A DFT study. Superlattices Microstruct 116:238–243CrossRef

319.

Esrafili MD, Nurazar RJS (2014) Microstructures, A density functional theory study on the adsorption and decomposition of methanol on B12N12 fullerene-like nanocage. Superlattices Microstruct 67:54–60CrossRef

320.

Matos J et al (2019) C-doped anatase TiO2: Adsorption kinetics and photocatalytic degradation of methylene blue and phenol, and correlations with DFT estimations. J Colloid Interface Sci 547:14–29CrossRef

321.

Zanjanchi F et al (2011) Photo-oxidation of phenylazonaphthol dyes and their reactivity analysis in the gas phase and adsorbed on cellulose fibers states using DFT and TD-DFT 89(1):16–22

322.

Zeng H et al (2018) Degradation of dyes by peroxymonosulfate activated by ternary CoFeNi-layered double hydroxide: Catalytic performance, mechanism and kinetic modeling. J Colloid Interface Sci 515:92–100CrossRef

Springer Professional

Elimination of dyes by catalytic reduction in the absence of light: A review

Abstract

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Premium Partners

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 28/2021

Degradable bio-based epoxy vitrimers based on imine chemistry and their application in recyclable carbon fiber composites

A novel and potentially scalable CVD-based route towards SnO2:Mo thin films as transparent conducting oxides

Ca-modified Al–Mg–Sc alloy with high strength at elevated temperatures due to a hierarchical microstructure

Microwave absorption performance of hierarchical structured composites of greigite and reduced graphene oxide

Microstructure development in eutectic Al–Fe alloy during directional solidification under high magnetic fields at different growth velocities

Acid-modulated porous AgI/D-MIL-53(Fe) composites for the removal of antibiotic contaminant

Premium Partners