|
|
Registro Completo |
Biblioteca(s): |
Embrapa Pecuária Sudeste. |
Data corrente: |
16/07/2007 |
Data da última atualização: |
01/09/2015 |
Autoria: |
MITRA, S. (ed.). |
Título: |
Sample preparation techniques in analytical chemistry. |
Ano de publicação: |
2003 |
Fonte/Imprenta: |
New Jersey: John Wiley & Sons, 2003. |
Páginas: |
458p. |
ISBN: |
0-471-32845-6 |
Idioma: |
Inglês |
Conteúdo: |
Sample preparation: an analytical perspective; Somenath Mitra and Roman Brukh;
The Measurement Process; Qualitative and Quantitative Analysis; Methods of Quantitation; Errors in Quantitative Analysis: Accuracy and Precision; Accuracy;
Precision; Statistical Aspects of Sample Preparation; Method Performance and Method Validation; Sensitivity; Detection Limit; Range of Quantitation; Other Important Parameters; Method Validation; Preservation of Samples; Volatilization; Choice of Proper Containers; Absorption of Gases from the Atmosphere; Chemical Changes;
Preservation of Unstable Solids; Postextraction Procedures; Concentration of Sample Extracts; Sample Cleanup; Quality Assurance and Qua1ity Control during Sample Preparation; Determination ofAccuracy and Precision; Statistical Control; Matrix Control;
Contamination Control; Extraction and enrichment in sample preparation; principles of extraction and the extraction of semivolatile organics from liqums; PrincipIes of Extraction; Volatization; Hydrophobicity; Acid-Base Equilibria; Distribution of Hydrophobic Ionogenic Organic Compounds; Liquid- Liquid Extraction; Recovery;
Methodology; Procedures; Recent Advances in Techniques; Liquid-Solid Extraction;
Sorption; Solid-Phase Extraction; Sorbents in SPE; Sorbent Selection; Recovery;
Methodology; Procedures; Recent Advances in SPE; Solid-Phase Microextraction;
Sorbents; Sorbent Selection; Methodology; Recent Advances in Techniques; Stir Bar Sorptive Extraction; Sorbent and Analyte Recovery; Methodology; Recent Advances in Techniques; Method Comparison; Extraction of semivolatile organic compounds from solid matrices; Extraction Mechanism; Preextraction Procedures; Postextraction Procedures; Soxhlet and Automated Soxhlet; Soxhlet Extraction; Automated Soxhlet Extraction; Comparison between Soxtec and Soxhlet; Ultrasonic Extraction; Selected Applications and Comparison with Soxhlet; Supercritical Fluid Extraction; Theoretical considerations; lnstrumentation; Operational Procedures; Advantagesi Disadvantages and Applications of SFE; Accelerated Solvent Extraction; Theoretical Considerations; lnstrurnentation; Operational Procedures; Process Parameters; Advantages and Applications of ASE; Microwave-Assisted Extraction; Theoretical Considerations;
lnstrurnentation; Procedures and Advantages/ Disadvantages; Process Parameters;
Applications of MAE; Comparison of the Various Extraction Techniques; Extraction of volatll..e organic compounds from solms and liquids; Volatile Organics and Their Analysis; Static Headspace Extraction; Sample Preparation for Static Headspace Extraction; Optimizin8 Static Headspace Extraction Efficiency and Quantitation;
Quantitative Techniques in Static Headspace Extraction; Dynamic Headspace Extraction or Purge and Trap; lnstrurnentation; Operational Procedures in Purge and Trap; lnterfacing Purge and Trap with GC; Solid-Phase Microextraction; SPME Method Development for Volatile Organics; Choosing an SPME Fiber Coating; Optimizing Extraction Conditions; Optimizing SPME-GC Injection; Liquid-Liquid Extraction with Large-Volume Injection; Large-Volurne GC Injection Techniques; Liquid-Liquid Extraction for Large- Volume Injection; Membrane Extraction; Membranes and Membrane Modules;
Membrane Introduction Mass Spectrometry; Membrane Extraction with Gas Chromatography; Optimization of Membrane Extraction; Preparallon of samples for metals analysis; Wet Digestion Methods; Acid Digestion-Wet Ashing; Microwave Digestion; Comparison of Digestion Methods; Pressure Ashing; Wet Ashing for Soil Samples; Dry Ashing; Organic Extraction of Metals; Extraction with Supercritical Fluids;
Ultrasonic Sample Preparation; Solid-Phase Extraction for Preconcentration; Sample Preparation for Water Samples; Precipitation Methods; Preparation of Sample Slurries for Direct AAS Analysis; Hydride Generation Methods; Colorimetric Methods; Metal Speciation; Types of Speciation; Speciation for Soils and Sediments; Sequential Schemes for MetaIs in Soil or Sediment; Speciation for MetaIs in Plant MateriaIs;
Speciation ofSpecific Elements; Contamination during Metal Analysis; Safe Handling of Acids; sample preparation for nucleic acm analysis;sample prepara non in dna analysis; DNA and Its Structure; Physical and Chemical Properties of DNA; Isolation of DNA; Isolation of DNA from Bacteria; Phenol Extraction and Precipitation of DNA;
Removal of Contaminants from DNA; Isolation of Plasmid DNA; Plasmid DNA preparation; Purification of Plasmid DNA; Genomic DNA Isolation from Yeast; DNA
from Mammalian Tissues; Blood; Tissues and Tissue Culture Cells; DNA from Plant Tissue; Isolation of Very High Molecular Weight DNA; DNA Amplification by Polymerase Chain Reaction; Starting a PCR Reaction; Isolation of DNA from Small Real-World Samples for PCR;Assessment of Quality and Quantitation of DNA; Precautions for preparing DNA; Assessment of Concentration and Quality; Storage of DNA; sample preparation in rna analysis; RNA: Structure and Properties; Types and Location of Various RNAs; RNA Isolation: Basic Considerations; Methods of Extraction and Isolation of RNA; Phenol Extraction and RNA Recovery: Basic PrincipIes; Examples of RNA Isolation Using Phenol Extraction; Guanidinium Salt Method; Examples of RNA Isolation Using Guanidinium Salts; Isolation of RNA from Nuclear and Cytoplasmic Cellular Fractions; Removal of DNA Contamination from RNA; Fractionation of RNA Using Chromatography Methods; Fractionation of Small RNA by HPLC; mRNA Iso1ation by Affinity Chromatography; Isolation of RNA from Small Numbers of Cells; In Vitro Synthesis of RNA; Assessment of Quality and Quantitation of RNA; Storage of RNA;
techniques for the extracnon, isolation, and purificanon of nucleic acms; Methods of Cell Lysis; Mechanical Methods of Cell Lysis; Nonmechanical Methods of Cell Lysis;
Isolation of Nuc1eic Acids; Solvent Extraction and Precipitation; Membrane Filtration;
Chromatographic Methods for the Purification of Nucleic Acids; Size-Exc1usion Chromatography; Anion-Exchange Chromatography; Solid-Phase Extraction; Affinity Purification; Automated High- Throughput DNA Purification Systems; Electrophoretic Separation of Nuc1eic Acids; Gel Electrophoresis for Nucleic Acids Purification;
Techniques for the Isolation of DNA from Gels; Capillary Electrophoresis for Sequencing and Sizing; Microfabricated Devices for Nucleic Acids Analysis; sample preparation on microchips; sample preparallon in microscopy and spectroscopy; sample preparation for microscopic and spectroscopic characterization of solm; surfaces and films;
Microscopy of Solids; Spectroscopic Techniques for Solids; Sample Preparation for Microscopic Evaluation; Sectioning and Polishing; Chemical and Thermal Etching;
Sample Coating Techniques; Specimen Thinning for TEM Analysis; Ion Milling;
Reactive Ion Techniques; Chemical Polishing and Electropolishing; Tripod Polishing;
Ultramicrotomy; Special Techniques and Variations; Summary: Sample Preparation for Microscopy; Sample Preparation for Surface Spectroscopy; Ion Bombardment; Sample Heating; In Situ Abrasion and Scraping; In Situ Cleavage or Fracture Stage; Sample Preparation Treatment Options for In Situ Reaction Studies; Summary: Sample Preparation for Surrare Spectroscopy; surface enhancement by sample and substrate preparation techniques in raman and infrared spectroscopy; Raman Effect; fundamentaIs of Surface-Enhanced Raman Spectroscopy; Attenuated Total Reflection Infrared Spectroscppy; FundamentaIs of Surface-Enhanced Infrared Spectroscopy;
Sample Preparation for SERS; Electrochemical Techniques; Vapor Deposition and Chemical Preparation Techniques; Colloidal Sol Techniques; Nanoparticle Arrays and Gratings; Sample Preparation for SEIRA; PotentiaI Applications. MenosSample preparation: an analytical perspective; Somenath Mitra and Roman Brukh;
The Measurement Process; Qualitative and Quantitative Analysis; Methods of Quantitation; Errors in Quantitative Analysis: Accuracy and Precision; Accuracy;
Precision; Statistical Aspects of Sample Preparation; Method Performance and Method Validation; Sensitivity; Detection Limit; Range of Quantitation; Other Important Parameters; Method Validation; Preservation of Samples; Volatilization; Choice of Proper Containers; Absorption of Gases from the Atmosphere; Chemical Changes;
Preservation of Unstable Solids; Postextraction Procedures; Concentration of Sample Extracts; Sample Cleanup; Quality Assurance and Qua1ity Control during Sample Preparation; Determination ofAccuracy and Precision; Statistical Control; Matrix Control;
Contamination Control; Extraction and enrichment in sample preparation; principles of extraction and the extraction of semivolatile organics from liqums; PrincipIes of Extraction; Volatization; Hydrophobicity; Acid-Base Equilibria; Distribution of Hydrophobic Ionogenic Organic Compounds; Liquid- Liquid Extraction; Recovery;
Methodology; Procedures; Recent Advances in Techniques; Liquid-Solid Extraction;
Sorption; Solid-Phase Extraction; Sorbents in SPE; Sorbent Selection; Recovery;
Methodology; Procedures; Recent Advances in SPE; Solid-Phase Microextraction;
Sorbents; Sorbent Selection; Methodology; Recent Advances in Techniques; Stir Bar Sorptive Extraction; Sorbent and ... Mostrar Tudo |
Palavras-Chave: |
Analitic methodology. |
Thesaurus Nal: |
chemistry; sampling. |
Categoria do assunto: |
-- |
Marc: |
LEADER 08224nam a2200169 a 4500 001 1042912 005 2015-09-01 008 2003 bl uuuu 00u1 u #d 020 $a0-471-32845-6 100 1 $aMITRA, S. 245 $aSample preparation techniques in analytical chemistry. 260 $aNew Jersey: John Wiley & Sons$c2003 300 $a458p. 520 $aSample preparation: an analytical perspective; Somenath Mitra and Roman Brukh; The Measurement Process; Qualitative and Quantitative Analysis; Methods of Quantitation; Errors in Quantitative Analysis: Accuracy and Precision; Accuracy; Precision; Statistical Aspects of Sample Preparation; Method Performance and Method Validation; Sensitivity; Detection Limit; Range of Quantitation; Other Important Parameters; Method Validation; Preservation of Samples; Volatilization; Choice of Proper Containers; Absorption of Gases from the Atmosphere; Chemical Changes; Preservation of Unstable Solids; Postextraction Procedures; Concentration of Sample Extracts; Sample Cleanup; Quality Assurance and Qua1ity Control during Sample Preparation; Determination ofAccuracy and Precision; Statistical Control; Matrix Control; Contamination Control; Extraction and enrichment in sample preparation; principles of extraction and the extraction of semivolatile organics from liqums; PrincipIes of Extraction; Volatization; Hydrophobicity; Acid-Base Equilibria; Distribution of Hydrophobic Ionogenic Organic Compounds; Liquid- Liquid Extraction; Recovery; Methodology; Procedures; Recent Advances in Techniques; Liquid-Solid Extraction; Sorption; Solid-Phase Extraction; Sorbents in SPE; Sorbent Selection; Recovery; Methodology; Procedures; Recent Advances in SPE; Solid-Phase Microextraction; Sorbents; Sorbent Selection; Methodology; Recent Advances in Techniques; Stir Bar Sorptive Extraction; Sorbent and Analyte Recovery; Methodology; Recent Advances in Techniques; Method Comparison; Extraction of semivolatile organic compounds from solid matrices; Extraction Mechanism; Preextraction Procedures; Postextraction Procedures; Soxhlet and Automated Soxhlet; Soxhlet Extraction; Automated Soxhlet Extraction; Comparison between Soxtec and Soxhlet; Ultrasonic Extraction; Selected Applications and Comparison with Soxhlet; Supercritical Fluid Extraction; Theoretical considerations; lnstrumentation; Operational Procedures; Advantagesi Disadvantages and Applications of SFE; Accelerated Solvent Extraction; Theoretical Considerations; lnstrurnentation; Operational Procedures; Process Parameters; Advantages and Applications of ASE; Microwave-Assisted Extraction; Theoretical Considerations; lnstrurnentation; Procedures and Advantages/ Disadvantages; Process Parameters; Applications of MAE; Comparison of the Various Extraction Techniques; Extraction of volatll..e organic compounds from solms and liquids; Volatile Organics and Their Analysis; Static Headspace Extraction; Sample Preparation for Static Headspace Extraction; Optimizin8 Static Headspace Extraction Efficiency and Quantitation; Quantitative Techniques in Static Headspace Extraction; Dynamic Headspace Extraction or Purge and Trap; lnstrurnentation; Operational Procedures in Purge and Trap; lnterfacing Purge and Trap with GC; Solid-Phase Microextraction; SPME Method Development for Volatile Organics; Choosing an SPME Fiber Coating; Optimizing Extraction Conditions; Optimizing SPME-GC Injection; Liquid-Liquid Extraction with Large-Volume Injection; Large-Volurne GC Injection Techniques; Liquid-Liquid Extraction for Large- Volume Injection; Membrane Extraction; Membranes and Membrane Modules; Membrane Introduction Mass Spectrometry; Membrane Extraction with Gas Chromatography; Optimization of Membrane Extraction; Preparallon of samples for metals analysis; Wet Digestion Methods; Acid Digestion-Wet Ashing; Microwave Digestion; Comparison of Digestion Methods; Pressure Ashing; Wet Ashing for Soil Samples; Dry Ashing; Organic Extraction of Metals; Extraction with Supercritical Fluids; Ultrasonic Sample Preparation; Solid-Phase Extraction for Preconcentration; Sample Preparation for Water Samples; Precipitation Methods; Preparation of Sample Slurries for Direct AAS Analysis; Hydride Generation Methods; Colorimetric Methods; Metal Speciation; Types of Speciation; Speciation for Soils and Sediments; Sequential Schemes for MetaIs in Soil or Sediment; Speciation for MetaIs in Plant MateriaIs; Speciation ofSpecific Elements; Contamination during Metal Analysis; Safe Handling of Acids; sample preparation for nucleic acm analysis;sample prepara non in dna analysis; DNA and Its Structure; Physical and Chemical Properties of DNA; Isolation of DNA; Isolation of DNA from Bacteria; Phenol Extraction and Precipitation of DNA; Removal of Contaminants from DNA; Isolation of Plasmid DNA; Plasmid DNA preparation; Purification of Plasmid DNA; Genomic DNA Isolation from Yeast; DNA from Mammalian Tissues; Blood; Tissues and Tissue Culture Cells; DNA from Plant Tissue; Isolation of Very High Molecular Weight DNA; DNA Amplification by Polymerase Chain Reaction; Starting a PCR Reaction; Isolation of DNA from Small Real-World Samples for PCR;Assessment of Quality and Quantitation of DNA; Precautions for preparing DNA; Assessment of Concentration and Quality; Storage of DNA; sample preparation in rna analysis; RNA: Structure and Properties; Types and Location of Various RNAs; RNA Isolation: Basic Considerations; Methods of Extraction and Isolation of RNA; Phenol Extraction and RNA Recovery: Basic PrincipIes; Examples of RNA Isolation Using Phenol Extraction; Guanidinium Salt Method; Examples of RNA Isolation Using Guanidinium Salts; Isolation of RNA from Nuclear and Cytoplasmic Cellular Fractions; Removal of DNA Contamination from RNA; Fractionation of RNA Using Chromatography Methods; Fractionation of Small RNA by HPLC; mRNA Iso1ation by Affinity Chromatography; Isolation of RNA from Small Numbers of Cells; In Vitro Synthesis of RNA; Assessment of Quality and Quantitation of RNA; Storage of RNA; techniques for the extracnon, isolation, and purificanon of nucleic acms; Methods of Cell Lysis; Mechanical Methods of Cell Lysis; Nonmechanical Methods of Cell Lysis; Isolation of Nuc1eic Acids; Solvent Extraction and Precipitation; Membrane Filtration; Chromatographic Methods for the Purification of Nucleic Acids; Size-Exc1usion Chromatography; Anion-Exchange Chromatography; Solid-Phase Extraction; Affinity Purification; Automated High- Throughput DNA Purification Systems; Electrophoretic Separation of Nuc1eic Acids; Gel Electrophoresis for Nucleic Acids Purification; Techniques for the Isolation of DNA from Gels; Capillary Electrophoresis for Sequencing and Sizing; Microfabricated Devices for Nucleic Acids Analysis; sample preparation on microchips; sample preparallon in microscopy and spectroscopy; sample preparation for microscopic and spectroscopic characterization of solm; surfaces and films; Microscopy of Solids; Spectroscopic Techniques for Solids; Sample Preparation for Microscopic Evaluation; Sectioning and Polishing; Chemical and Thermal Etching; Sample Coating Techniques; Specimen Thinning for TEM Analysis; Ion Milling; Reactive Ion Techniques; Chemical Polishing and Electropolishing; Tripod Polishing; Ultramicrotomy; Special Techniques and Variations; Summary: Sample Preparation for Microscopy; Sample Preparation for Surface Spectroscopy; Ion Bombardment; Sample Heating; In Situ Abrasion and Scraping; In Situ Cleavage or Fracture Stage; Sample Preparation Treatment Options for In Situ Reaction Studies; Summary: Sample Preparation for Surrare Spectroscopy; surface enhancement by sample and substrate preparation techniques in raman and infrared spectroscopy; Raman Effect; fundamentaIs of Surface-Enhanced Raman Spectroscopy; Attenuated Total Reflection Infrared Spectroscppy; FundamentaIs of Surface-Enhanced Infrared Spectroscopy; Sample Preparation for SERS; Electrochemical Techniques; Vapor Deposition and Chemical Preparation Techniques; Colloidal Sol Techniques; Nanoparticle Arrays and Gratings; Sample Preparation for SEIRA; PotentiaI Applications. 650 $achemistry 650 $asampling 653 $aAnalitic methodology
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Embrapa Pecuária Sudeste (CPPSE) |
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Biblioteca(s): |
Embrapa Milho e Sorgo. |
Data corrente: |
25/03/2015 |
Data da última atualização: |
10/06/2015 |
Tipo da produção científica: |
Documentos |
Autoria: |
RIBEIRO, P. E. de A.; BARROS, L. C. de; BATISTA, E. J.; ALBUQUERQUE FILHO, M. R. de; SANTOS, M. A. dos; FARIA, C. M. de; MOURA, L. O. |
Afiliação: |
PAULO EDUARDO DE AQUINO RIBEIRO, CNPMS; LUCIANO CORDOVAL DE BARROS, CNPMS; ERMANO JOSE BATISTA, CNPMS; MANOEL RICARDO DE ALBUQUERQUE FILHO, CNPMS; MARCOS AURELIO DOS SANTOS, CNPMS; CARLA MOREIRA DE FARIA, CNPMS; LARISSA OLIVEIRA MOURA, Estagiária. |
Título: |
Caracterização e melhorias no canal de irrigação da Embrapa Milho e Sorgo. |
Ano de publicação: |
2014 |
Fonte/Imprenta: |
Sete Lagoas: Embrapa Milho e Sorgo, 2014. |
Páginas: |
28 p. |
Série: |
(Embrapa Milho e Sorgo. Documentos, 173). |
Idioma: |
Português |
Conteúdo: |
A irrigação é uma técnica indispensável na pesquisa agropecuária, visto que só é possível estudar as diversas variáveis de uma cultura de forma isolada se sua sustentabilidade hídrica estiver bem estabelecida e garantida. O canal de irrigação da Embrapa Milho e Sorgo é uma estrutura artificialmente construída para levar água às diversas áreas da fazenda experimental. Sua caracterização e mapeamento foi exigida no processo de licenciamento ambiental da Unidade, para demonstrar que não trata-se de um curso d’água natural. Nesse documento, apresentamos essa caracterização física, assim como algumas importantes melhorias que são necessárias para sua conservação e para racionalização do uso desse importante recurso natural: a água. |
Palavras-Chave: |
Captação de água; Racionalização do uso da água; Uso da água. |
Thesagro: |
Abastecimento de água. |
Categoria do assunto: |
-- |
URL: |
https://ainfo.cnptia.embrapa.br/digital/bitstream/item/125186/1/doc-173.pdf
|
Marc: |
LEADER 01557nam a2200253 a 4500 001 2012125 005 2015-06-10 008 2014 bl uuuu u0uu1 u #d 100 1 $aRIBEIRO, P. E. de A. 245 $aCaracterização e melhorias no canal de irrigação da Embrapa Milho e Sorgo.$h[electronic resource] 260 $aSete Lagoas: Embrapa Milho e Sorgo$c2014 300 $a28 p. 490 $a(Embrapa Milho e Sorgo. Documentos, 173). 520 $aA irrigação é uma técnica indispensável na pesquisa agropecuária, visto que só é possível estudar as diversas variáveis de uma cultura de forma isolada se sua sustentabilidade hídrica estiver bem estabelecida e garantida. O canal de irrigação da Embrapa Milho e Sorgo é uma estrutura artificialmente construída para levar água às diversas áreas da fazenda experimental. Sua caracterização e mapeamento foi exigida no processo de licenciamento ambiental da Unidade, para demonstrar que não trata-se de um curso d’água natural. Nesse documento, apresentamos essa caracterização física, assim como algumas importantes melhorias que são necessárias para sua conservação e para racionalização do uso desse importante recurso natural: a água. 650 $aAbastecimento de água 653 $aCaptação de água 653 $aRacionalização do uso da água 653 $aUso da água 700 1 $aBARROS, L. C. de 700 1 $aBATISTA, E. J. 700 1 $aALBUQUERQUE FILHO, M. R. de 700 1 $aSANTOS, M. A. dos 700 1 $aFARIA, C. M. de 700 1 $aMOURA, L. O.
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