Organisk syntes - METTLER TOLEDO
Organic Synthesis Applications

Organisk syntes

Screening och optimering av katalys, hydrering, polymersyntes och andra reaktiva kemiska synteser

Ring för offert
Syntetisk organisk kemi
Förbättra katalysatorprestandan för tandemhydroformylering/-hydrering
Reaktionsövervakning i realtid
Experimentdesign för optimerade reaktionsförhållanden
Arbetsstationer för organisk syntes
Syntetisera genombrottsmolekyler
Högreaktiv kemi

Applikationer

Synthetic Organic Chemistry Applications

Control Residual Isocyanate
Process Analytical Technology for Continuous Measurement of NCO

Isocyanates are critical building blocks for high performance polyurethane-based polymers that make up coatings, foams, adhesives, elastomers, and insulation. Concerns over exposure to residual isocyanates led to new limits for residual isocyanates in new products. Traditional analytical methods for measuring the residual isocyanate (NCO) concentration using offline sampling and analysis raise concerns. In situ monitoring with process analytical technology addresses these challenges and enables manufacturers and formulators to ensure that product quality specifications, personnel safety, and environmental regulations are met.

Measuring Polymerization Reactions
Methods and Techniques to Develop Synthetic Polymer Chemistry

Polymerization reaction measurement is crucial to produce material that meets requirements, including Immediate understanding, accurate and reproducible, Improved safety.

Impurity Profiling of Chemical Reactions
Automated Process Development Strategies for Chemists

Impurity profiling aims at identification and subsequent quantification of specific components present at low levels, usually less than 1% and ideally lower than 0.1 %.

Grignard Reaction Mechanisms
Understand and Control Exothermic Events

Grignard reactions are one of the most important reaction classes in organic chemistry. Grignard reactions are useful for forming carbon-carbon bonds. Grignard reactions form alcohols from ketones and aldehydes, as well as react with other chemicals to form a myriad of useful compounds. Grignard reactions are performed using a Grignard reagent, which is typically a alkyl-, aryl- or vinyl- organomagnesium halide compound. To ensure optimization and safety of Grignard reactions in research, development and production, in situ monitoring and understanding reaction heat flow is important.

Hydrogenation Reactions
Safe Reaction Monitoring at Elevated Temperature and Pressure

Hydrogenation reactions are used in the manufacturing of both bulk and fine chemicals for reducing multiple bonds to single bonds. Catalysts are typically used to promote these reactions and reaction temperature, pressure, substrate loading, catalyst loading, and agitation rate all effect hydrogen gas uptake and overall reaction performance. Thorough understanding of this energetic reaction is important and PAT technology in support of HPLC analysis ensure safe, optimized and well-characterized chemistry.

Highly Reactive Chemistries
Scale-Up and Optimize Highly Reactive Chemistries

Highly reactive chemistry is a terminology used to describe chemical reactions that are particularly challenging to handle and develop due to the potentially hazardous and/or energetic nature of the reactants, intermediates and products that are present during synthesis. These chemistries often involve highly exothermic reactions which require specialized equipment or extreme operating conditions (such as low temperature) to ensure adequate control. Ensuring safe operating conditions, minimizing human exposure, and gaining the maximum amount of information from each experiment are key factors in successfully designing and scaling-up highly reactive chemistries.

High Pressure Reactions
Understand and Characterize High Pressure Reactions Under Challenging Sampling Conditions

Many processes require reactions to be run under high pressure. Working under pressure is challenging and collecting samples for offline analysis is difficult and time consuming. A change in pressure could affect reaction rate, conversion and mechanism as well as other process parameters plus sensitivity to oxygen, water, and associated safety issues are common problems.

Halogenation Reactions
Key Syntheses in Pharmaceutical and Polymer Chemistry

Halogenation occurs when one of more fluorine, chlorine, bromine, or iodine atoms replace one or more hydrogen atoms in an organic compound. Depending on the specific halogen, the nature of the substrate molecule and overall reaction conditions, halogenation reactions can be very energetic and follow different pathways. For this reason, understanding these reactions from a kinetics and thermodynamic perspective is critical to ensuring yield, quality and safety of the process.

Catalytic Reactions
Accelerate Chemical Reactions With a Catalyst

Catalysts create an alternative path to increase the speed and outcome of a reaction, so a thorough understanding of the reaction kinetics is important. Not only does that provide information about the rate of the reaction, but also provides insight into the mechanism of the reaction. There are two types of catalytic reactions: heterogeneous and homogeneous. Heterogeneous is when the catalyst and reactant exist in two different phases. Homogeneous is when the catalyst and the reactant are in the same phase..

Syntes reaktioner
Tillhandahålla automatiserade verktyg för att leverera livsförändrande produkter

En syntesreaktion är en kemisk process där enkla element eller föreningar kombineras för att bilda en mer komplex produkt. Det representeras av ekvationen: A + B → AB.

Design of Experiments (DoE)
A Statistical Approach to Reaction Optimization

Design of Experiments (DoE) requires experiments to be conducted under well-controlled and reproducible conditions in chemical process optimization. Chemical synthesis reactors are designed to perform DoE investigations ensuring high quality data.

Reaction Mechanism Pathway
Fundamental Understanding of Chemical Reactions and Factors Affecting Them

Reaction mechanisms describe the successive steps at the molecular level that take place in a chemical reaction. Reaction mechanisms cannot be proven, but rather postulated based on empirical experimentation and deduction. In situ FTIR spectroscopy provides information to support reaction mechanisms hypotheses.

Organometallic Synthesis
Understanding and Control of Organometallic Compounds

Organometallic Synthesis, or Organometallic Chemistry, refers to the process of creating organometallic compounds, and is among the most researched areas in chemistry. Organometallic compounds are frequently used in fine chemical syntheses and to catalyze reactions. In situ Infrared and Raman spectroscopy are among the most powerful analytical methods for the study of organometallic compounds and syntheses.

Oligonucleotide Synthesis
Ensure Yield, Purity, and Cost Objectives

Oligonucleotide synthesis is the chemical process by which nucleotides are specifically linked to form a product of desired sequenced.

What is Alkylation?
For Key Reactions in Organic Chemistry

Alkylation is the process by when an alkyl group is added to a substrate molecule. Alkylation reactions are a widely used technique in organic chemistry.

Epoxides
Key Functional Groups for Synthesis of Polymers and Pharmaceuticals

This page outlines what epoxides are, how they are synthesized and technology to track reaction progression, including kinetics and key mechanisms.

Key C-C Bond-Forming Reactions in Molecular Synthesis

The Suzuki and related cross-coupling reactions use transition metal catalysts, such as palladium complexes, to form C-C bonds between alkyl and aryl halides with various organic compounds.

Lithiation Organolithium Reactions
Key Reagents for Synthesizing Complex Molecules

Lithiation and organolithium reactions are key in the development of complex pharmaceutical compounds; organolithium compounds also act as initiators in certain polymerization reactions.

Functionalization of Carbon Bonds

C-H bond activation is a series of mechanistic processes by which stable carbon-hydrogen bonds in organic compounds are cleaved.

Organocatalysis
For Metal-Free Asymmetric Synthesis of Chiral Molecules

Organocatalysis refers to the employment of particular organic molecules to speed up chemical reactions through catalytic activation.

hydroformylation reaction example
Understanding Key Mechanisms and Improve Catalytic Processes

Hydroformylation, also known as oxo synthesis, is a chemical reaction involving the addition of carbon monoxide (CO) and hydrogen (H₂) to an unsaturated compound, typically an alkene or alkyne. The reaction is catalyzed by transition metal complexes, such as rhodium or cobalt, leading to the formation of aldehydes or aldehyde derivatives.

click chemistry tools for click reactions
In-Situ Chemistry to Support Click Reactions

Click reactions refer to chemical reactions that meet the criteria of click chemistry. Click reactions are typically fast, high-yielding, and occur under mild conditions, making them ideal for a variety of applications.

Reaktorer med kontinuerlig omrörd tank CSTR
Flödesteknik för kemiska och biologiska synteser

En kontinuerlig omrörd tankreaktor (CSTR) är ett kärl i vilket reagenser och reaktanter strömmar in i en reaktor, medan reaktionsprodukten lämnar kärlet.

Control Residual Isocyanate

Isocyanates are critical building blocks for high performance polyurethane-based polymers that make up coatings, foams, adhesives, elastomers, and insulation. Concerns over exposure to residual isocyanates led to new limits for residual isocyanates in new products. Traditional analytical methods for measuring the residual isocyanate (NCO) concentration using offline sampling and analysis raise concerns. In situ monitoring with process analytical technology addresses these challenges and enables manufacturers and formulators to ensure that product quality specifications, personnel safety, and environmental regulations are met.

Measuring Polymerization Reactions

Polymerization reaction measurement is crucial to produce material that meets requirements, including Immediate understanding, accurate and reproducible, Improved safety.

Impurity Profiling of Chemical Reactions

Impurity profiling aims at identification and subsequent quantification of specific components present at low levels, usually less than 1% and ideally lower than 0.1 %.

Grignard Reaction Mechanisms

Grignard reactions are one of the most important reaction classes in organic chemistry. Grignard reactions are useful for forming carbon-carbon bonds. Grignard reactions form alcohols from ketones and aldehydes, as well as react with other chemicals to form a myriad of useful compounds. Grignard reactions are performed using a Grignard reagent, which is typically a alkyl-, aryl- or vinyl- organomagnesium halide compound. To ensure optimization and safety of Grignard reactions in research, development and production, in situ monitoring and understanding reaction heat flow is important.

Hydrogenation Reactions

Hydrogenation reactions are used in the manufacturing of both bulk and fine chemicals for reducing multiple bonds to single bonds. Catalysts are typically used to promote these reactions and reaction temperature, pressure, substrate loading, catalyst loading, and agitation rate all effect hydrogen gas uptake and overall reaction performance. Thorough understanding of this energetic reaction is important and PAT technology in support of HPLC analysis ensure safe, optimized and well-characterized chemistry.

Highly Reactive Chemistries

Highly reactive chemistry is a terminology used to describe chemical reactions that are particularly challenging to handle and develop due to the potentially hazardous and/or energetic nature of the reactants, intermediates and products that are present during synthesis. These chemistries often involve highly exothermic reactions which require specialized equipment or extreme operating conditions (such as low temperature) to ensure adequate control. Ensuring safe operating conditions, minimizing human exposure, and gaining the maximum amount of information from each experiment are key factors in successfully designing and scaling-up highly reactive chemistries.

High Pressure Reactions

Many processes require reactions to be run under high pressure. Working under pressure is challenging and collecting samples for offline analysis is difficult and time consuming. A change in pressure could affect reaction rate, conversion and mechanism as well as other process parameters plus sensitivity to oxygen, water, and associated safety issues are common problems.

Halogenation Reactions

Halogenation occurs when one of more fluorine, chlorine, bromine, or iodine atoms replace one or more hydrogen atoms in an organic compound. Depending on the specific halogen, the nature of the substrate molecule and overall reaction conditions, halogenation reactions can be very energetic and follow different pathways. For this reason, understanding these reactions from a kinetics and thermodynamic perspective is critical to ensuring yield, quality and safety of the process.

Catalytic Reactions

Catalysts create an alternative path to increase the speed and outcome of a reaction, so a thorough understanding of the reaction kinetics is important. Not only does that provide information about the rate of the reaction, but also provides insight into the mechanism of the reaction. There are two types of catalytic reactions: heterogeneous and homogeneous. Heterogeneous is when the catalyst and reactant exist in two different phases. Homogeneous is when the catalyst and the reactant are in the same phase..

Syntes reaktioner

En syntesreaktion är en kemisk process där enkla element eller föreningar kombineras för att bilda en mer komplex produkt. Det representeras av ekvationen: A + B → AB.

Design of Experiments (DoE)

Design of Experiments (DoE) requires experiments to be conducted under well-controlled and reproducible conditions in chemical process optimization. Chemical synthesis reactors are designed to perform DoE investigations ensuring high quality data.

Reaction Mechanism Pathway

Reaction mechanisms describe the successive steps at the molecular level that take place in a chemical reaction. Reaction mechanisms cannot be proven, but rather postulated based on empirical experimentation and deduction. In situ FTIR spectroscopy provides information to support reaction mechanisms hypotheses.

Organometallic Synthesis

Organometallic Synthesis, or Organometallic Chemistry, refers to the process of creating organometallic compounds, and is among the most researched areas in chemistry. Organometallic compounds are frequently used in fine chemical syntheses and to catalyze reactions. In situ Infrared and Raman spectroscopy are among the most powerful analytical methods for the study of organometallic compounds and syntheses.

Oligonucleotide Synthesis

Oligonucleotide synthesis is the chemical process by which nucleotides are specifically linked to form a product of desired sequenced.

What is Alkylation?

Alkylation is the process by when an alkyl group is added to a substrate molecule. Alkylation reactions are a widely used technique in organic chemistry.

Epoxides

This page outlines what epoxides are, how they are synthesized and technology to track reaction progression, including kinetics and key mechanisms.

The Suzuki and related cross-coupling reactions use transition metal catalysts, such as palladium complexes, to form C-C bonds between alkyl and aryl halides with various organic compounds.

Lithiation Organolithium Reactions

Lithiation and organolithium reactions are key in the development of complex pharmaceutical compounds; organolithium compounds also act as initiators in certain polymerization reactions.

C-H bond activation is a series of mechanistic processes by which stable carbon-hydrogen bonds in organic compounds are cleaved.

Organocatalysis

Organocatalysis refers to the employment of particular organic molecules to speed up chemical reactions through catalytic activation.

hydroformylation reaction example

Hydroformylation, also known as oxo synthesis, is a chemical reaction involving the addition of carbon monoxide (CO) and hydrogen (H₂) to an unsaturated compound, typically an alkene or alkyne. The reaction is catalyzed by transition metal complexes, such as rhodium or cobalt, leading to the formation of aldehydes or aldehyde derivatives.

click chemistry tools for click reactions

Click reactions refer to chemical reactions that meet the criteria of click chemistry. Click reactions are typically fast, high-yielding, and occur under mild conditions, making them ideal for a variety of applications.

Reaktorer med kontinuerlig omrörd tank CSTR

En kontinuerlig omrörd tankreaktor (CSTR) är ett kärl i vilket reagenser och reaktanter strömmar in i en reaktor, medan reaktionsprodukten lämnar kärlet.

Trycksaker

Publications on Synthetic Organic Chemistry

White Papers

Tekniker för att syntetisera genombrottsmolekyler
Framsteg inom organisk kemi gör det möjligt för forskare att utöka FoU för molekyler och optimera processförhållanden. Ett nytt white paper presentera...
”The Modern Synthesis Lab”
I denna vitbok beskrivs en ny verktygslåda utformad för kemister som ger fler experimentalternativ, automatiserar tråkiga uppgifter och samlar in högk...
Metal Catalyzed Transformations Using In Situ Spectroscopy
This white paper reviews recent advances in organic chemistry using chemical reaction monitoring.
In situ-övervakning av kemiska reaktioner
”Hur gör man mer med mindre?” är ett konstant ämne på kemikaliska utvecklingslaboratorier då forskare behöver få fram kemiprodukter snabbt och kostnad...
Process FTIR för säker användning av natriumborohydridreduktion
John O'Reilly från Roche Ireland pratar om hållbar processanalysteknik (PAT) med process FTIR för säker användning av natriumborohydridreduktion.
tandem hydroformylation hydrogenation
Real time, in-situ mid-FTIR reaction monitoring leads to a greater understanding of catalyst activity and robustness. Researchers at the University of...
Grignard-reaktion uppskalning – 4 steg för att kontrollera utveckling
Exotermiska reaktioner har inneboende risker – särskilt vid uppskalning. Publicerade studier från ledande kemi- och läkemedelsföretag visar att genom...
Snabb analys av kontinuerliga experiment med reaktionsoptimering
Detta white paper – Snabb analys av experiment med reaktionsoptimering – behandlar hur man kan optimera kemiska reaktioner.

Webbseminarier

Hydrogenation Under High Pressure
This presentation discusses the implementation of Fourier Transform Infrared (FTIR) reaction monitoring technology to provide knowledge and understand...
Impact of Process Intensification on Process Safety
This presentation discusses how Nalas Engineering safely handles high energy materials and hazardous chemistry.
Reaction Kinetics Progress Analysis Ryan Baxter
This webinar explores a graphical analysis approach to rationalize unusual kinetics in C-H activations. The Reaction Progress Kinetic Analysis (RPKA)...
Hydrogenation Under High Pressure
This presentation discusses the implementation of Fourier Transform Infrared (FTIR) reaction monitoring technology to provide knowledge and understand...
DoE to Peptide Synthesis
Learn how Design of Experiments (DoE) is applied to chemical synthesis at Lonza Peptide.

Relaterade produkter

Synthetic Organic Chemistry Tools