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Trace elements in water. --- Water --- Ferric oxide. --- Purification --- Adsorption.
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"Object Lessons is a series of short, beautifully designed books about the hidden lives of ordinary things. It's happening all the time, all around us. We cover it up. We ignore it. Rust takes on the many meanings of this oxidized substance, showing how technology bleeds into biology and ecology. Jean-Michel Rabaté combines art, science, and autobiography to share his fascination with peeling paints and rusty metal sheets. Rust, he concludes, is a place where things living, built, and remembered commingle. Object Lessons is published in partnership with an essay series in The Atlantic" -- From the publisher.
Metals --- Corrosion and anti-corrosives --- Metals in literature. --- Oxidation --- Ferric oxide --- Social aspects. --- Philosophy.
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Nanomedicine. --- Ferric oxide --- Nanoparticles. --- Nano-particles --- NPs (Nanoparticles) --- Nanostructured materials --- Particles --- Ferric trioxide --- Iron oxide --- Ironic oxide --- Red ferric oxide --- Red iron oxide --- Red iron trioxide --- Iron oxides --- Medicine --- Nanotechnology --- Magnetic properties. --- Nanoscale particles
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Adsorption --- Ferric oxide --- Surface chemistry --- 541.183 --- 541.183 Contact systems. Adsorption. Surface chemistry --- Contact systems. Adsorption. Surface chemistry --- Chemistry, Surface --- Interfaces, Chemistry of --- Surface phenomena --- Surfaces (Chemistry) --- Chemistry, Physical and theoretical --- Capillarity --- Surface energy --- Surface tension --- Surfaces (Physics) --- Ferric trioxide --- Iron oxide --- Ironic oxide --- Red ferric oxide --- Red iron oxide --- Red iron trioxide --- Iron oxides --- Sorption --- Separation (Technology) --- Hydrosphere --- fysicochemie
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Sandra Haschke presents a strategy to enhance the Fe2O3 electrode performance by controlled nanostructuring of the catalyst surface, based on anodized aluminum oxide coated by means of atomic layer deposition. Furthermore, she investigates the influence of underlying conductive layers and post-deposition annealing on the electrode performance and the associated changes in morphology and chemical composition. Exploiting all effects combined delivers an increase in steady-state water oxidation throughput by a factor of 2.5 with respect to planar electrodes. Contents Preparation of Nanostructured Fe2O3 Electrodes Chemical and Structural Properties of Nanoporous Catalyst Electrodes Modification of Nanostructured Fe2O3 Electrodes by Means of Post-Deposition Annealing Improvement of Electrode Performance by Surface Area Enhancement Target Groups Researchers and students in the fields of electrochemistry, materials sciences and physical chemistry Practitioners in these areas The Author Sandra Haschke obtained her Master’s degree in chemistry at the Friedrich-Alexander University Erlangen-Nürnberg under the supervision of Prof. Dr. Julien Bachmann where she will continue with her PhD thesis.
Energy. --- Renewable and Green Energy. --- Catalysis. --- Nanotechnology. --- Renewable energy sources. --- Catalyse --- Energies renouvelables --- Nanotechnologie --- Mechanical Engineering --- Engineering & Applied Sciences --- Mechanical Engineering - General --- Oxidation. --- Water --- Electrochemistry. --- Ferric oxide. --- Ferric trioxide --- Iron oxide --- Ironic oxide --- Red ferric oxide --- Red iron oxide --- Red iron trioxide --- Autoxidation --- Renewable energy resources. --- Alternate energy sources. --- Green energy industries. --- Iron oxides --- Chemistry, Physical and theoretical --- Hydrology --- Molecular technology --- Nanoscale technology --- High technology --- Activation (Chemistry) --- Surface chemistry --- Alternate energy sources --- Alternative energy sources --- Energy sources, Renewable --- Sustainable energy sources --- Power resources --- Renewable natural resources --- Agriculture and energy
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In this first full-scale attempt to reconstruct the chemical evolution of the Earth's atmosphere and oceans, Heinrich Holland assembles data from a wide spectrum of fields to trace the history of the ocean-atmosphere system. A pioneer in an increasingly important area of scholarship, he presents a comprehensive treatment of knowledge on this subject, provides an extensive bibliography, and outlines problems and approaches for further research.The first four chapters deal with the turbulent first half billion years of Earth history. The next four chapters, devoted largely to the Earth from 3.9 to 0.6 b.y.b.p., demonstrate that changes in the atmosphere and oceans during this period were not dramatic. The last chapter of the book deals with the Phanerozoic Eon; although the isotopic composition of sulfur and strontium in seawater varied greatly during this period of Earth history, the chemical composition of seawater did not.
Atmospheric chemistry. --- Chemical oceanography. --- Molecular evolution. --- Achondrites. --- Albian. --- Aluminum. --- Anhydrite. --- Ankerite. --- Banded iron formations. --- Bicarbonate. --- Biotite. --- Calcite. --- Carbon. --- Carbonate sediments. --- Devonian. --- Diagenesis. --- Dolomitization. --- Evaporites. --- Ferric oxide. --- Graphite. --- Halite. --- Hydrogen. --- Igneous rocks. --- Jasper. --- Jurassic. --- Krypton. --- Lithium. --- Magnesium. --- Marine sediments. --- Metamorphism. --- Mid-ocean ridges. --- Nitric acid. --- North American Platform. --- Organic carbon. --- Oxidation reactions. --- Paleosols. --- Phanerozoic. --- Precambrian. --- Proterozoic. --- Quartz. --- Rare gases. --- Russian Platform. --- Sedimentary rocks. --- Tertiary.
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A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
Environmental science, engineering & technology --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- n/a
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A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- n/a
Choose an application
A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
Environmental science, engineering & technology --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal
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