2020
Doing nano-enabled water treatment right: sustainability considerations from design and research through development and implementation
Falinski M, Turley R, Kidd J, Lounsbury A, Lanzarini-Lopes M, Backhaus A, Rudel H, Lane M, Fausey C, Barrios A, Loyo-Rosales J, Perreault F, Walker W, Stadler L, Elimelech M, Gardea-Torresdey J, Westerhoff P, Zimmerman J. Doing nano-enabled water treatment right: sustainability considerations from design and research through development and implementation. Environmental Science Nano 2020, 7: 3255-3278. DOI: 10.1039/d0en00584c.Peer-Reviewed Original ResearchConventional water treatment systemsWater treatment systemsUnique physicochemical propertiesBroad electromagnetic spectrumFundamental nanoscienceTreatment systemWater treatmentIndustrial wastewater treatmentWater treatment technologiesWater treatment devicesConventional water treatmentPerformance enhancementWastewater treatmentElectromagnetic spectrumTreatment technologiesIndustrial wastewaterPhysicochemical propertiesTreatment devicesSustainability considerationsDevicesWorld lack accessNanoscienceTechnology developmentContaminants of concernNano
2016
A Strategy for Material Supply Chain Sustainability: Enabling a Circular Economy in the Electronics Industry through Green Engineering
O’Connor M, Zimmerman J, Anastas P, Plata D. A Strategy for Material Supply Chain Sustainability: Enabling a Circular Economy in the Electronics Industry through Green Engineering. ACS Sustainable Chemistry & Engineering 2016, 4: 5879-5888. DOI: 10.1021/acssuschemeng.6b01954.Peer-Reviewed Original ResearchGreen engineeringFabrication efficiencyElectronic technologyComplex waste streamsE-waste recoveryDesign devicesElectronics industryRecycled materialsSpecialty elementsManufacturing processE-waste componentsWaste streamsCircular economyMaterial supply chainSame materialTechnologyEngineeringRapid innovationElectronicsMaterialsDevicesTechnical researchRare earthIndustry oneEfficiency