Mercury nano-trap for effective and efficient removal of mercury(II) from aqueous solution

Li, Baiyan; Zhang, Yiming; Ma, Dingxuan; Shi, Zhan; Ma, Shengqian

doi:10.1038/ncomms6537

Cited by 497 publications

(333 citation statements)

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“…A final concentration of 910 ppb was measured, thus indicating approximately 55 % of the inorganic mercury was removed with a single treatment. While alternative, and highly effective, mercury sensors17 and adsorbents18 have been reported, their deployment in environmental remediation is often limited due to the challenges and cost of their large‐scale synthesis 15a, 16. We note that the sulfur‐limonene polysulfide is comparatively inexpensive, easy to produce on a large scale, and displays a useful chromogenic response.…”

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confidence: 99%

Sulfur‐Limonene Polysulfide: A Material Synthesized Entirely from Industrial By‐Products and Its Use in Removing Toxic Metals from Water and Soil

et al. 2015

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A polysulfide material was synthesized by the direct reaction of sulfur and d‐limonene, by‐products of the petroleum and citrus industries, respectively. The resulting material was processed into functional coatings or molded into solid devices for the removal of palladium and mercury salts from water and soil. The binding of mercury(II) to the sulfur‐limonene polysulfide resulted in a color change. These properties motivate application in next‐generation environmental remediation and mercury sensing.

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confidence: 99%

Sulfur‐Limonene Polysulfide: A Material Synthesized Entirely from Industrial By‐Products and Its Use in Removing Toxic Metals from Water and Soil

et al. 2015

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“…Afinal concentration of 910 ppb was measured, thus indicating approximately 55 %o ft he inorganic mercury was removed with as ingle treatment. While alternative,a nd highly effective,m ercury sensors [17] and adsorbents [18] have been reported, their deployment in environmental remediation is often limited due to the challenges and cost of their large-scale synthesis. [15a,16] We note that the sulfur-limonene polysulfide is comparatively inexpensive,e asy to produce on alarge scale,and displays auseful chromogenic response.…”

Section: Methodsmentioning

confidence: 99%

Sulfur‐Limonene Polysulfide: A Material Synthesized Entirely from Industrial By‐Products and Its Use in Removing Toxic Metals from Water and Soil

et al. 2015

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Apolysulfide material was synthesized by the direct reaction of sulfur and d-limonene,b y-products of the petroleum and citrus industries,r espectively.T he resulting material was processed into functional coatings or molded into solid devices for the removal of palladium and mercury salts from water and soil. The binding of mercury(II) to the sulfurlimonene polysulfide resulted in acolor change.These properties motivate application in next-generation environmental remediation and mercury sensing.The exploration of sustainable feedstocks is important in the synthesis of functional materials.[1] Herein, we report the utility of apolysulfide synthesized directly from two industrial by-products:s ulfur [2] and d-limonene [3] (Scheme 1). This study was inspired by classic reports on the reaction of sulfur and limonene, [4] theu se of limonene as ar enewable monomer, [5] and the recent and innovative applications of "inverse vulcanization" to access av ariety of advanced materials with high sulfur content. [6] We found that the sulfur-limonene polysulfide can be processed into coatings and solid devices that remove metal salts such as palladium-(II) and mercury(II) from water and soil. We also report the discovery of ac hromogenic response when the polysulfide is exposed to mercury(II). As sulfur is produced annually in excess of 60 million tons as ab y-product of petroleum refining [2] and more than 70 thousand tons of limonene are isolated each year from orange zest in the citrus industry, [3] the sulfur-limonene polysulfide is inexpensive-further motivating its use in metal sequestration, sensing,and environmental remediation.As as tarting point, sulfur was melted (T > 120 8 8C) and then heated to 170 8 8C. Above 150 8 8C, SÀSb ond scission occurs, [7] thereby generating thiyl radicals that could add to limonene.A ne qual mass of limonene was added to the molten sulfur,w hich produced at wo-phase mixture that becomes as ingle,d ark red phase upon reaction. An equal mass of sulfur and limonene was chosen to maximize the content of both industrial by-products in the final material. 1 HNMR analysis of the reaction mixture indicated limonenes exocyclic alkene was consumed more rapidly than its endocyclic alkene,w ith complete consumption of all olefins within 90 min (see Figures S6-S8 in the Supporting Information). Little change was observed by 1 HNMR spectroscopy on further heating. Scheme 1. Synthesis and applicationso fasulfur-limonene polysulfide.

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“…Among all of the existing techniques developed over the past years for water treatment, adsorption has been demonstrated to be one of the most effective and convenient approaches due to its simple operation and energy effectiveness 3. Usually, ideal adsorbents should possess the following features: perfect selectivity,4 multiple adsorbability,5 strong affinity,[[qv: 3c]],6 good reusability,5, 6, 7 no secondary pollution,5, 8 rapid kinetics,9 and high adsorption capacity. [[qv: 3c]] Although many adsorbents have been created, the ideal adsorbent is still to be discovered since some of these features are internally contradictory.…”

Section: Introductionmentioning

confidence: 99%

A Targeted “Capture” and “Removal” Scavenger toward Multiple Pollutants for Water Remediation based on Molecular Recognition

Wang

Shen

et al. 2015

Advanced Science

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For the water remediation techniques based on adsorption, the long‐standing contradictories between selectivity and multiple adsorbability, as well as between affinity and recyclability, have put it on weak defense amid more and more severe environment crisis. Here, a pollutant‐targeting hydrogel scavenger is reported for water remediation with both high selectivity and multiple adsorbability for several pollutants, and with strong affinity and good recyclability through rationally integrating the advantages of multiple functional materials. In the scavenger, aptamers fold into binding pockets to accommodate the molecular structure of pollutants to afford perfect selectivity, and Janus nanoparticles with antibacterial function as well as anisotropic surfaces to immobilize multiple aptamers allow for simultaneously handling different kinds of pollutants. The scavenger exhibits high efficiencies in removing pollutants from water and it can be easily recycled for many times without significant loss of loading capacities. Moreover, the residual concentrations of each contaminant are well below the drinking water standards. Thermodynamic behavior of the adsorption process is investigated and the rate‐controlling process is determined. Furthermore, a point of use device is constructed and it displays high efficiency in removing pollutants from environmental water. The scavenger exhibits great promise to be applied in the next generation of water purification systems.

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Mercury nano-trap for effective and efficient removal of mercury(II) from aqueous solution

Cited by 497 publications

References 58 publications

Sulfur‐Limonene Polysulfide: A Material Synthesized Entirely from Industrial By‐Products and Its Use in Removing Toxic Metals from Water and Soil

Sulfur‐Limonene Polysulfide: A Material Synthesized Entirely from Industrial By‐Products and Its Use in Removing Toxic Metals from Water and Soil

Sulfur‐Limonene Polysulfide: A Material Synthesized Entirely from Industrial By‐Products and Its Use in Removing Toxic Metals from Water and Soil

A Targeted “Capture” and “Removal” Scavenger toward Multiple Pollutants for Water Remediation based on Molecular Recognition

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