Search results for "Acid–base reaction"

showing 7 items of 7 documents

A predictive model for salt nanoparticle formation using heterodimer stability calculations

2021

Acid–base clusters and stable salt formation are critical drivers of new particle formation events in the atmosphere. In this study, we explore salt heterodimer (a cluster of one acid and one base) stability as a function of gas-phase acidity, aqueous-phase acidity, heterodimer proton transference, vapor pressure, dipole moment and polarizability for salts comprised of sulfuric acid, methanesulfonic acid and nitric acid with nine bases. The best predictor of heterodimer stability was found to be gas-phase acidity. We then analyzed the relationship between heterodimer stability and J4×4, the theoretically predicted formation rate of a four-acid, four-base cluster, for sulfuric acid salts ove…

Atmospheric Sciencesuolat010504 meteorology & atmospheric sciencesVapor pressureQC1-999Salt (chemistry)Thermodynamics01 natural sciencesMethanesulfonic acidilmakemiachemistry.chemical_compoundNitric acid0103 physical sciencesSulfateQD1-9990105 earth and related environmental scienceschemistry.chemical_classificationaerosolit010304 chemical physicsPhysicsSulfuric acidChemistryMonomerchemistrynanoparticlesnanohiukkasetAcid–base reaction
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Deklarierung von Infusionslösungen mit Base Excess (BE) und potentiellem Base Excess (BEpot)

1995

Drug labelingRadiochemistryGeneral MedicineCritical Care and Intensive Care MedicinePlasma SubstitutesLactic acidchemistry.chemical_compoundAnesthesiology and Pain MedicineFluid therapychemistryCarbon dioxideEmergency MedicineBase excessAcid–base reactionAINS - Anästhesiologie · Intensivmedizin · Notfallmedizin · Schmerztherapie
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Histamine, an effective initiator for the synthesis of polysulfides

2020

The synthesis of polysulfides from thioepoxides traditionally makes use of toxic organometallic initiators. We demonstrate the use of histamine as an efficient initiator. The polymerization can be carried out under solvent-free and metal-free conditions at mild temperature to obtain high-quality polysulfides. A synergistic acid and base catalysis mechanism is proposed. The results enable a safer and cleaner production of next-generation polymers.

Fluid Flow and Transfer Processeschemistry.chemical_classificationChemistryProcess Chemistry and TechnologyPolymerCombinatorial chemistryCatalysisCatalysischemistry.chemical_compoundPolymerizationChemistry (miscellaneous)Chemical Engineering (miscellaneous)Acid–base reactionHistamineReaction Chemistry & Engineering
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Energy harvesting by waste acid/base neutralization via bipolar membrane reverse electrodialysis

2020

Bipolar Membrane Reverse Electrodialysis (BMRED) can be used to produce electricity exploiting acid-base neutralization, thus representing a valuable route in reusing waste streams. The present work investigates the performance of a lab-scale BMRED module under several operating conditions. By feeding the stack with 1 M HCl and NaOH streams, a maximum power density of ~17 W m−2 was obtained at 100 A m−2 with a 10-triplet stack with a flow velocity of 1 cm s−1, while an energy density of ~10 kWh m−3 acid could be extracted by a complete neutralization. Parasitic currents along feed and drain manifolds significantly affected the performance of the stack when equipped with a higher number of t…

Work (thermodynamics)Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciControl and OptimizationMaterials scienceEnergy Engineering and Power TechnologySalt (chemistry)02 engineering and technology010501 environmental sciencespH gradient; waste to energy; ion-exchange membrane; wastewater valorization; controlled neutralization7. Clean energy01 natural scienceslcsh:TechnologyStack (abstract data type)Reversed electrodialysisWastewater valorizationElectrical and Electronic EngineeringIon-exchange membraneEngineering (miscellaneous)pH gradient0105 earth and related environmental sciencesPower densitychemistry.chemical_classificationRenewable Energy Sustainability and the Environmentlcsh:T021001 nanoscience & nanotechnology6. Clean waterWaste to energyMembraneSettore ING-IND/23 - Chimica Fisica ApplicatachemistryFlow velocityChemical engineeringAcid–base reaction0210 nano-technologyControlled neutralizationEnergy (miscellaneous)
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Solution Properties and Potential Biological Applications of Zwitterionic Poly(ε-N-methacryloyl-l-lysine)

2013

Poly(e-N-methacryloyl-l-lysine) (PMALys) was synthesized by free radical polymerization yielding a zwitterionic polymer with Mw = 721 000 g mol–1. The polymer dissolves in pure water as well as in aqueous salt solution up to 5 M NaClO4 and over wide range of pH values (1.3 ≤ pH ≤ 12.7) as single chains without any sign for aggregate formation. The zwitterionic polymer shows an expanded random coil structure at and close to isoelectric conditions and further expands upon addition of acid and base, respectively. The polymer fulfills four major prerequisites for a promising nano carrier in potential biomedical applications: (1) It is biocompatible, indicated by a low cytotoxicity. (2) It does …

chemistry.chemical_classificationAqueous solutionPolymers and PlasticsChemistryOrganic ChemistryLysineRadical polymerizationPolymerRandom coilInorganic ChemistryIsoelectric pointPolymer chemistryMaterials ChemistryAcid–base reactionCytotoxicityMacromolecules
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Low-protein vegetarian diet does not have a short-term effect on blood acid–base status but raises oxygen consumption during submaximal cycling

2012

Abstract Background Acid–base balance refers to the equilibrium between acids and bases in the human body. Nutrition may affect acid–base balance and further physical performance. With the help of PRAL (potential renal acid load), a low-protein vegetarian diet (LPVD) was designed to enhance the production of bases in body. The aim of this study was to investigate if LPVD has an effect on blood acid–base status and performance during submaximal and maximal aerobic cycling. Methods Nine healthy, recreationally active men (age 23.5 ± 3.4 yr) participated in the study and were randomly divided into two groups in a cross-over study design. Group 1 followed LPVD for 4 days and group 2 ate normall…

medicine.medical_specialtyLow proteinAcid–base balancechemistry.chemical_elementlcsh:TX341-641Clinical nutritionAcid–base homeostasisOxygenMedicineTerm effectFood sciencelcsh:Sports medicineNutritionNutrition and Dieteticsbusiness.industryAerobic performanceAcid loadchemistryPhysical therapyAcid–base reactionlcsh:RC1200-1245businessCyclinglcsh:Nutrition. Foods and food supplyFood ScienceResearch ArticleJournal of the International Society of Sports Nutrition
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The accuracy of calculated base excess in blood.

2002

Most equations used for calculation of the base excess (BE, mmol/l) in human blood are based on the fundamental equation derived by Siggaard-Andersen and called the Van Slyke equation: BE = Z x [[cHCO3-(P) - C7.4 HCO3-(P)] + beta x (pH -7.4)]. In simple approximation, where Z is a constant which depends only on total hemoglobin concentration (cHb, g/dl) in blood, three equations were tested: the ones proposed by Siggaard-Andersen (SA), the National Committee for Clinical Laboratory Standards (NCCLS) or Zander (ZA). They differ only slightly in the solubility factor for carbon dioxide (alphaCO2, mmol/l x mmHg) and in the apparent pK(pK'), but more significantly in the plasma bicarbonate conc…

medicine.medical_specialtySimple equationPartial PressureClinical BiochemistryAnalytical chemistrypCO2HemoglobinsReference ValuesmedicineMethodsHumansSolubilityWhole bloodAcid-Base EquilibriumHuman bloodChemistryBiochemistry (medical)Reproducibility of ResultsGeneral MedicineCarbon DioxideHydrogen-Ion ConcentrationSurgeryOxygenBicarbonatesBloodChemistry ClinicalArterial bloodBase excessAcid–base reactionClinical chemistry and laboratory medicine
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