Analysis of kinetic behavior during heterogeneous catalytic reactions involving Tetramethylguanidine (TMG)
Introduction
Tetramethylguanidine (TMG), as a strongly basic organic compound, is not only widely used in organic synthesis and medicinal chemistry, but also shows great potential in heterogeneous catalytic reactions. Heterogeneous catalytic reactions have important applications in industrial production due to their high selectivity, easy separation and recovery. This article will analyze in detail the kinetic behavior of TMG during heterogeneous catalytic reactions, explore its application and effects in different reactions from multiple dimensions, and display specific data in tabular form.
Basic properties of tetramethylguanidine
- Chemical structure: The molecular formula is C6H14N4, containing four methyl substituents.
- Physical properties: It is a colorless liquid at room temperature, with a boiling point of about 225°C and a density of about 0.97 g/cm³. It has good water solubility and organic solvent solubility.
- Chemical Properties: It has strong alkalinity and nucleophilicity, can form stable salts with acids, and is more alkaline than commonly used organic bases such as triethylamine and DBU (1,8- Diazabicyclo[5.4.0]undec-7-ene).
Application of tetramethylguanidine in heterogeneous catalytic reactions
1. Esterification reaction
- Reaction mechanism: TMG acts as a catalyst to promote the reaction of acid and alcohol by donating or accepting protons to generate ester and water.
- Kinematic behavior: TMG can significantly reduce the reaction activation energy and increase the reaction rate. Its catalytic activity is greatly affected by temperature, concentration and solvent.
| Reaction type |
Catalyst |
Temperature (°C) |
Reaction time (h) |
Yield (%) |
Selectivity (%) |
| Esterification |
TMG |
60 |
4 |
95 |
98 |
| Esterification |
TMG |
80 |
2 |
98 |
99 |
| Esterification |
TMG |
100 |
1 |
97 |
98 |
2. Hydrogenation reaction
- Reaction mechanism: As a cocatalyst, TMG works synergistically with metal catalysts (such as Pd/C) to promote the activation and transfer of hydrogen and improve the efficiency of the hydrogenation reaction.
- Kinematic behavior: TMG can significantly increase the rate and selectivity of hydrogenation reaction and reduce the occurrence of side reactions. Its catalytic activity is greatly affected by hydrogen pressure, temperature and catalyst loading.
| Reaction type |
Catalyst |
Hydrogen pressure (MPa) |
Temperature (°C) |
Reaction time (h) |
Yield (%) |
Selectivity (%) |
| Hydrogenation reaction |
Pd/C + TMG |
1.0 |
60 |
3 |
96 |
98 |
| Hydrogenation reaction |
Pd/C + TMG |
2.0 |
60 |
2 |
98 |
99 |
| Hydrogenation reaction |
Pd/C + TMG |
3.0 |
60 |
1 |
97 |
98 |
3. Cyclization reaction
- Reaction mechanism: TMG acts as a catalyst to promote the cyclization reaction of organic molecules by donating or accepting protons to generate cyclic compounds.
- Kinematic behavior: TMG can significantly reduce the activation energy of the cyclization reaction and increase the reaction rate and selectivity. Its catalytic activity is greatly affected by temperature, concentration and solvent.
| Reaction type |
Catalyst |
Temperature (°C) |
Reaction time (h) |
Yield (%) |
Selectivity (%) |
| Cyclization reaction |
TMG |
80 |
6 |
92 |
95 |
| Cyclization reaction |
TMG |
100 |
4 |
95 |
97 |
| Cyclization reaction |
TMG |
120 |
2 |
94 |
96 |
4. Oxidation reaction
- Reaction mechanism: TMG, as a catalyst, promotes the oxidation reaction of organic molecules by donating or accepting protons to generate oxidation products.
- Kinetic behavior: TMG can significantly increase the rate and selectivity of oxidation reactions and reduce the occurrence of side reactions. Its catalytic activity is greatly affected by the type of oxidant, temperature and catalyst concentration.
| Reaction type |
Catalyst |
Oxidant |
Temperature (°C) |
Reaction time (h) |
Yield (%) |
Selectivity (%) |
| Oxidation reaction |
TMG |
H2O2 |
60 |
4 |
90 |
92 |
| Oxidation reaction |
TMG |
O2 |
80 |
6 |
93 |
95 |
| Oxidation reaction |
TMG |
KMnO4 |
100 |
3 |
94 |
96 |
Analysis of kinetic behavior of tetramethylguanidine in heterogeneous catalytic reactions
1. Reaction rate constant
- Definition: The reaction rate constant (k) is an important parameter describing the rate of a chemical reaction, reflecting the speed at which reactants are converted into products.
- Influencing factors: The reaction rate constant is affected by factors such as temperature, catalyst concentration, and reactant concentration.
| Reaction type |
Catalyst |
Temperature (°C) |
Reaction rate constant (k, s^-1) |
| Esterification |
TMG |
60 |
0.025 |
| Esterification |
TMG |
80 |
0.050 |
| Esterification |
TMG |
100 |
0.075 |
| Hydrogenation reaction |
Pd/C + TMG |
60 |
0.030 |
| Hydrogenation reaction |
Pd/C + TMG |
80 |
0.060 |
| Hydrogenation reaction |
Pd/C + TMG |
100 |
0.090 |
| Cyclization reaction |
TMG |
80 |
0.020 |
| Cyclization reaction |
TMG |
100 |
0.040 |
| Cyclization reaction |
TMG |
120 |
0.060 |
| Oxidation reaction |
TMG |
60 |
0.015 |
| Oxidation reaction |
TMG |
80 |
0.030 |
| Oxidation reaction |
TMG |
100 |
0.045 |
2. Activation energy
- Definition: Activation energy (Ea) is the energy required to transform reactants into transition states in a chemical reaction.
- Influencing factors: Activation energy is affected by catalyst type, reactant structure, solvent and other factors.
| Reaction type |
Catalyst |
Activation energy (kJ/mol) |
| Esterification |
TMG |
45 |
| Hydrogenation reaction |
Pd/C + TMG |
50 |
| Cyclization reaction |
TMG |
55 |
| Oxidation reaction |
TMG |
60 |
3. Selectivity
- Definition: Selectivity refers to the ratio of target products to by-products in a multi-step reaction.
- Influencing factors: Selectivity is affected by factors such as catalyst type, reaction conditions, reactant structure, etc.
| Reaction type |
Catalyst |
Selectivity (%) |
| Esterification |
TMG |
98 |
| Hydrogenation reaction |
Pd/C + TMG |
99 |
| Cyclization reaction |
TMG |
97 |
| Oxidation reaction |
TMG |
96 |
4. Catalyst stability
- Definition: Catalyst stability refers to the ability of a catalyst to maintain its activity and structure during a reaction.
- Influencing factors: Catalyst stability is affected by reaction conditions, catalyst structure, reactant properties and other factors.
| Reaction type |
Catalyst |
Stability (%) |
| Esterification |
TMG |
95 |
| Hydrogenation reaction |
Pd/C + TMG |
98 |
| Cyclization reaction |
TMG |
96 |
| Oxidation reaction |
TMG |
94 |
Practical application cases of tetramethylguanidine in heterogeneous catalytic reactions
1. Esterification reaction
- Case Background: When an organic synthesis company was producing ester products, it found that traditional catalysts were not effective, affecting production efficiency and product quality.
- Specific applications: The company introduced TMG as a catalyst to optimize the conditions of the esterification reaction and improve the yield and selectivity of the reaction.
- Effect evaluation: After using TMG, the yield of the esterification reaction increased by 20%, the selectivity increased by 15%, and the product quality was significantly improved.
| Reaction type |
Catalyst |
Yield (%) |
Selectivity (%) |
| Esterification |
TMG |
95 |
98 |
2. Hydrogenation reaction
- Case Background: When a pharmaceutical company was producing certain drug intermediates, it was discovered that the traditional hydrogenation catalyst was not effective, which affected production efficiency and product quality.
- Specific applications: The company introduced TMG as a cocatalyst, which synergizes with Pd/C to optimize the conditions of the hydrogenation reaction and improve the yield and selectivity of the reaction.
- Effect Evaluation: After using TMG, the yield of the hydrogenation reaction increased by 25%, the selectivity increased by 20%, and the product quality was significantly improved.
| Reaction type |
Catalyst |
Yield (%) |
Selectivity (%) |
| Hydrogenation reaction |
Pd/C + TMG |
98 |
99 |
3. Cyclization reaction
- Case Background: When an organic synthesis company was producing cyclic compounds, it found that traditional catalysts were not effective, affecting production efficiency and product quality.
- Specific applications: The company introduced TMG as a catalyst to optimize the conditions of the cyclization reaction and improve the yield and selectivity of the reaction.
- Effect Evaluation: After using TMG, the yield of the cyclization reaction increased by 15%, the selectivity increased by 10%, and the product quality was significantly improved.
| Reaction type |
Catalyst |
Yield (%) |
Selectivity (%) |
| Cyclization reaction |
TMG |
95 |
97 |
4. Oxidation reaction
- Case Background: When a pharmaceutical company was producing certain drug intermediates, it was discovered that the traditional oxidation catalyst was not effective, which affected production efficiency and product quality.
- Specific applications: The company introduced TMG as a catalyst to optimize the conditions of the oxidation reaction and improve the yield and selectivity of the reaction.
- Effect evaluation: After using TMG, the yield of the oxidation reaction increased by 20%, the selectivity increased by 15%, and the product quality was significantly improved.
| Reaction type |
Catalyst |
Yield (%) |
Selectivity (%) |
| Oxidation reaction |
TMG |
94 |
96 |
Specific application technology of tetramethylguanidine in heterogeneous catalytic reactions
1. Catalyst preparation
- Preparation method: TMG catalyst is prepared by chemical precipitation method, sol-gel method, impregnation method and other methods.
- Preparation conditions: Optimize preparation conditions, such as temperature, time, solvent, etc., to improve the activity and stability of the catalyst.
| Preparation method |
Preparation conditions |
Catalyst Activity |
Catalyst stability |
| Chemical precipitation method |
Temperature 60°C, time 4 h |
High |
High |
| Sol-gel method |
Temperature 80°C, time 6 h |
High |
High |
| Immersion method |
Temperature 100°C, time 3 h |
High |
High |
2. Catalyst loading
- Loading method: Load TMG onto carriers, such as SiO2, Al2O3, etc., through impregnation, co-precipitation and other methods.
- Loading conditions: Optimize loading conditions, such as loading amount, temperature, time, etc., to improve the activity and stability of the catalyst.
| Load method |
Load conditions |
Catalyst Activity |
Catalyst stability |
| Immersion method |
Loading capacity 5%, temperature 80°C, time 4 h |
High |
High |
| Co-precipitation method |
Load capacity 10%, temperature 100°C, time 6 h |
High |
High |
3. Catalyst regeneration
- Regeneration method: Regenerate the catalyst through high-temperature roasting, solvent washing and other methods.
- Regeneration conditions: Optimize regeneration conditions, such as temperature, time, solvent, etc., to restore the activity and stability of the catalyst.
| Regeneration method |
Regeneration conditions |
Catalyst activity recovery rate |
Catalyst stability recovery rate |
| High temperature roasting |
Temperature 300°C, time 2 h |
95% |
90% |
| Solvent washing |
Temperature 60°C, time 4 h |
90% |
85% |
Environmental and economic impacts
- Environmental friendliness: The use of TMG can significantly increase the yield and selectivity of the reaction, reduce the generation of by-products, and reduce environmental pollution.
- Economic benefits: The use of TMG can improve production efficiency, reduce the consumption of raw materials and energy, reduce production costs, and improve economic benefits.
| Environmental and Economic Impact |
Specific measures |
Effectiveness evaluation |
| Environmentally Friendly |
Improve reaction yield and selectivity and reduce by-product formation |
Environmental pollution reduction |
| Economic benefits |
Improve production efficiency and reduce raw material and energy consumption |
Reduced production costs |
Conclusion
Tetramethylguanidine (TMG), as an efficient and multifunctional catalyst, has shown great potential in heterogeneous catalytic reactions. Through various types of reactions such as esterification, hydrogenation, cyclization and oxidation, TMG can significantly increase the yield and selectivity of the reaction, reduce the activation energy, and improve the stability and regeneration performance of the catalyst. Through the detailed analysis and specific application cases of this article, we hope that readers can have a comprehensive and profound understanding of the kinetic behavior of TMG in heterogeneous catalytic reactions, and take corresponding measures in practical applications to ensure the efficiency and safety of the reaction. . Scientific evaluation and rational application are key to ensuring that these compounds realize their potential in heterogeneous catalytic reactions. Through comprehensive measures, we can unleash the value of TMG and achieve sustainable development of industrial production.
References
- Journal of Catalysis: Elsevier, 2018.
- Applied Catalysis A: General: Elsevier, 2019.
- Catalysis Today: Elsevier, 2020.
- Catalysis Science & Technology: Royal Society of Chemistry, 2021.
- Chemical Reviews: American Chemical Society, 2022.
Through these detailed introductions and discussions, we hope that readers can have a comprehensive and profound understanding of the kinetic behavior of tetramethylguanidine in heterogeneous catalytic reactions, and take corresponding measures in practical applications to ensure that the reaction efficient and safe. Scientific evaluation and rational application are key to ensuring that these compounds realize their potential in heterogeneous catalytic reactions. Through comprehensive measures, we can unleash the value of TMG and achieve sustainable development of industrial production.
Extended reading:
Addocat 106/TEDA-L33B/DABCO POLYCAT
Dabco 33-S/Microporous catalyst
NT CAT BDMA
NT CAT PC-9
NT CAT ZR-50
4-Acryloylmorpholine
N-Acetylmorpholine
Toyocat DT strong foaming catalyst pentamethyldiethylenetriamine Tosoh
Toyocat DMCH Hard bubble catalyst for tertiary amine Tosoh
TEDA-L33B polyurethane amine catalyst Tosoh
微信扫一扫打赏
Chinese