Two-stage experimental design for dose-response modeling in toxicology studiesA new stochastic kriging method for modeling multi-source exposure-response data in toxicology studiesIn vivo evaluation of the pulmonary toxicity of cellulose nanocrystals: a renewable and sustainable nanomaterial of the futureEnvironmental Life Cycle Analysis of Distributed Three-Dimensional Printing and Conventional Manufacturing of Polymer ProductsA Safer Formulation Concept for Flame-Generated Engineered NanomaterialsCharacterization and Comparison of Fast Pyrolysis Bio-oils from Pinewood, Rapeseed Cake, and Wheat Straw Using (13)C NMR and Comprehensive GC × GCContinuous Flow Metathesis for Direct Valorization of Food Waste: An Example of Cocoa Butter TriglycerideSeparation of Lignin from Corn Stover Hydrolysate with Quantitative Recovery of Ionic LiquidComparison of Nonprecious Metal Cathode Materials for Methane Production by ElectromethanogenesisHigh-Power 365 nm UV LED Mercury Arc Lamp Replacement for Photochemistry and Chemical PhotolithographyImpedance Biosensors: Applications to Sustainability and Remaining Technical Challenges.Catalytic Upgrading in Bacteria-Compatible Conditions via a Biocompatible Aldol Condensation.Characterization of Rice Straw Prehydrolyzates and Their Effect on the Hydrolysis of Model Substrates Using a Commercial endo-Cellulase, β-Glucosidase and Cellulase CocktailHomocomposites of Polylactide (PLA) with Induced Interfacial Stereocomplex Crystallites.Cellulose, Chitosan and Keratin Composite Materials: Facile and Recyclable Synthesis, Conformation and Properties.Adsorption of a Protein Monolayer via Hydrophobic Interactions Prevents Nanoparticle Aggregation under Harsh Environmental Conditions.Enhancing the antioxidant characteristics of phenolic acids by their conversion into cholinium salts.Mild and Selective Protein Release of Cell Wall Deficient Microalgae with Pulsed Electric FieldSolution-Based Fabrication of Polycrystalline Si Thin-Film Transistors from Recycled Polysilanes.Synergy in Lignin Upgrading by a Combination of Cu-Based Mixed Oxide and Ni-Phosphide Catalysts in Supercritical Ethanol.Experimental Studies on the Hydrotreatment of Kraft Lignin to Aromatics and Alkylphenolics Using Economically Viable Fe-Based Catalysts.Recovery of Volatile Fatty Acids from Fermented Wastewater by AdsorptionCytotoxicity of ZnO Nanoparticles Can Be Tailored by Modifying Their Surface Structure: A Green Chemistry Approach for Safer NanomaterialsCatalytic Depolymerization of Lignin and Woody Biomass in Supercritical Ethanol: Influence of Reaction Temperature and Feedstock.Heat-Treated Stainless Steel Felt as a New Cathode Material in a Methane-Producing Bioelectrochemical System.Scale-up of a Luminescent Solar Concentrator-Based Photomicroreactor via Numbering-up.Understanding the Effect of the Dianhydride Structure on the Properties of Semiaromatic Polyimides Containing a Biobased Fatty Diamine.Functionalization of flat sheet and hollow fiber microfiltration membranes for water applications.Response to Comment on "Turning Vulcanized Natural Rubber into a Self-Healing Polymer: Effect of the Disulfide/Polysulfide Ratio".Laccase/Mediator Systems: Their Reactivity toward Phenolic Lignin Structures.High Rate Biomethanation of Carbon Monoxide-Rich Gases via a Thermophilic Synthetic Coculture.Divalent Cation Removal by Donnan Dialysis for Improved Reverse Electrodialysis.Toward the Rational Design of Sustainable Hair Dyes Using Cheminformatics Approaches: Step 1. Database Development and AnalysisSynthesis of Bio-aromatics from Black Liquors Using Catalytic Pyrolysis.Lewis Acid Catalyzed Conversion of 5-Hydroxymethylfurfural to 1,2,4-Benzenetriol, an Overlooked Biobased Compound.Correction to Comparison of Nonprecious Metal Cathode Materials for Methane Production by Electromethanogenesis.Toward "Green" Hybrid Materials: Core-Shell Particles with Enhanced Impact Energy Absorbing Ability.Energy-Efficient Ammonia Recovery in an Up-Scaled Hydrogen Gas Recycling Electrochemical System.Effect of n-Caproate Concentration on Chain Elongation and Competing Processes.Phosphate Recovery from Human Waste via the Formation of Hydroxyapatite during Electrochemical Wastewater Treatment.
P1433
Q23915830-8B65B8ED-C0B5-4C72-9856-B8313E208B18Q23915831-9E29BC4F-0829-42A4-8EC6-6923FFE0360BQ23918815-724938CE-8A7C-4D86-8FDB-32CEA5C6BDE7Q28314817-53603D10-4A73-4565-A6BA-62EE4BD8424AQ28387342-B6442AD2-A8F1-439B-9C9B-F82A915461A1Q28595595-AF21DFF6-2CE7-4684-B46B-30D20036A35BQ28608529-D5E4BC74-681F-4AC3-8291-828B98684809Q28650071-703F1BB9-DEBF-462E-A811-E3B38C8C251BQ28660242-EC49EBB8-0CCF-4611-B931-AAFE24464080Q28818143-BA1A1BD6-859C-487B-8710-C10BF260ED39Q30409507-83F71A12-EE11-4D72-A91F-7884EE8822D1Q33638221-47D549E6-0417-4E08-86D4-7497EDF9FCB6Q34194429-49AB1C67-E6ED-44E9-AC76-086741525859Q36185294-2DCDFA00-14AD-47EA-9981-16A8E89EAD16Q36956410-1301DB01-F9F7-4730-A00A-5AE6EDCEF8EDQ37063788-552199EC-3F3C-4A05-B54E-6F93D9D74E9CQ37671790-14F47DFD-66F0-4176-A021-D7F8109CB208Q40968733-1A44E0A6-5F03-4767-ABA3-DB0CE90D6C6EQ40968748-58AECE11-79B0-4A63-832F-FDD260BD4C84Q41846170-E84BC26D-C4A9-44F9-A8DD-A46A7848FEEEQ41993711-AA5A0CC3-EBD8-432A-BBEE-A17F144BA3DAQ42016754-49E89D8F-5582-4059-BC8F-A7159ACFEF94Q42115795-25F18D9B-BD82-4C68-8490-E86735B0B079Q47124453-5177E25A-4716-4D13-9DF9-15FD185B0E74Q47151261-35599EAF-9672-420B-8734-1704842395BBQ48538063-4897588B-D5A9-4F2E-9E50-8B98F961DEB8Q49168898-920DB79C-5CC5-4824-8DEF-6BD6F9598D26Q49314002-5D527B4E-A68D-4F4C-B2CC-2F6AAE552359Q49345418-76FB2198-0FAD-4C91-BC63-60C91FB5BD28Q49521724-513B9EF3-9934-4374-8582-5D2DC25A2D4DQ50073162-5189F441-1FDB-4A63-A839-8F47DE8EC78EQ53821852-41F64EC4-B29F-4FA9-A39F-E0EA4E3801D8Q54376606-C98C2C9B-ECA9-4192-87A7-93CE6F20EC96Q55021938-4C2C24C0-A698-49B3-8172-DFFEE8AA70B7Q55024581-DDB396BE-12CB-4382-8AF5-51A8E56405E9Q55035585-99878724-8511-4AFF-8997-3A2B73763C68Q55262293-58195681-537B-4DED-9836-2F5214932342Q55311468-1FA38134-6FD0-4E5F-8F5B-2195604943A4Q55342790-2CBAF95B-469F-4ED0-BB94-0D00FCAEAAD2Q55359388-17312C85-0A1E-496B-BC3C-715A2983081E
P1433
description
Fachzeitschrift
@de
Journal
@en
name
ACS Sustainable Chemistry & Engineering
@de
ACS Sustainable Chemistry & Engineering
@en
ACS Sustainable Chemistry & Engineering
@es
ACS Sustainable Chemistry & Engineering
@it
type
label
ACS Sustainable Chemistry & Engineering
@de
ACS Sustainable Chemistry & Engineering
@en
ACS Sustainable Chemistry & Engineering
@es
ACS Sustainable Chemistry & Engineering
@it
prefLabel
ACS Sustainable Chemistry & Engineering
@de
ACS Sustainable Chemistry & Engineering
@en
ACS Sustainable Chemistry & Engineering
@es
ACS Sustainable Chemistry & Engineering
@it
P3181
P1055
P1156
21100248891
P1277
P236
P3181
P407
P571
2013-01-01T00:00:00Z