Source: Laboratory of Dr. Ryan Richards — Colorado School of Mines
Catalysis is among the most important fields of modern technology and presently accounts for approximately 35% of the gross domestic product (GDP) and sustenance of approximately 33% of the global population through fertilizers produced via the Haber process.1 Catalysts are systems that facilitate chemical reactions by lowering the activation energy and influencing the selectivity. Catalysis will be a central technology in addressing the energy and environmental challenges of modern times.
Heterogeneous catalysts typically consist of a nanoscale catalytic entity (typically a metal) dispersed on a support material (typically carbon or metal oxide), which increases the surface area and often imparts some stability against aggregation of the nanoparticles. The catalyst nanoparticle has active sites on its surface, where the reaction takes place. Depending on the reaction, these active sites could be planar faces or crystal edges on the surface of the particle. Typically, smaller nanoparticles have higher catalytic activity, due to the higher amount of surface atoms per mole of catalyst.2
The reaction on the catalyst surface begins with adsorption of the reagents to the active site, followed by the reaction on the surface. The surface reaction can occur between one adsorbed species and one in the bulk, called the Eley-Rideal mechanism, or between two adsorbed species, called the Langmuir-Hinshelwood mechanism. The reacted species then desorbs from the surface into the bulk.2
Supported nanoscale palladium particles have shown activity in many important catalytic reactions and represent a model system for demonstrating a heterogeneous catalyst. Palladium based catalyst research efforts are broad and have ranged from upgrading of biomass to the decomposition of chemical dyes in wastewater streams. The use of palladium catalysts as a representative for heterogeneous catalysts is desirable because it allows facile separation of the catalyst from the products.2
Here, the heterogeneous catalyst consists of nanoscale palladium particles dispersed on a high surface area carbon support. Presently, several supported palladium catalysts are commercially available. In this educational article, two commercially available supported palladium materials are used, 1% palladium supported on active carbon and 0.5% palladium supported on granular carbon. Another material, active carbon, is used as a control experiment. The reduction of 4-nitrophenol is chosen for the catalytic reaction because it is easy to work with and the results are visible through a color change. This experimental protocol provides a very clear visual demonstration of a typical catalytic reaction.
1. Preparation of 4-Nitrophenol Solution Mixed with Sodium Borohydride
2. Preparation of Catalyst Solution
3. Catalytic Reduction of 4-Nitrophenol
Catalysts are substances that are added to chemical systems to enable chemical reactions to occur faster, using less energy.
The minimum amount of energy required to initiate a reaction is called the activation energy. Catalysts provide an alternate reaction pathway with a lower activation energy, allowing the reaction to take place under less extreme conditions. The activation energy is described by the Arrhenius equation.
Enzymes are biological molecules that behave as extremely specific catalysts. Enzymes are shape specific, and guide reactant molecules, called substrates, into the optimal configuration for reaction. Homogeneous catalysts are in the same phase as the reactants. Most frequently, the catalyst and reactants are both dissolved in the liquid phase. In heterogeneous catalysis, the catalyst and reactants are in different phases, separated by a phase boundary. Commonly, heterogeneous catalysts are solid and consist of a nano-scale catalytic entity, typically a metal nanoparticle, which is dispersed on a support material.
The support material, usually carbon, silica, or a metal oxide, is used to increase the surface area and impart stability against aggregation of the nanoparticles. Porous membranes and beads, mesh, and stacked sheets are some of the support geometries used in catalysis.
In heterogeneous catalysis, nanoparticles have active sites on the surface, where the reaction takes place. Depending on the reaction, these active sites could be planar faces or crystal edges on the surface of the particle. Typically, smaller nanoparticles have higher catalytic activity, due to the higher amount of surface atoms per mole of catalyst.
This video will highlight the basics of catalysis, and demonstrate how to perform a basic catalytic reaction in the laboratory.
There are several types of catalysts. At high temperature, molecules move faster and collide more frequently. Since the proportion of molecular collisions is higher, the reactants have enough energy to overcome the activation energy of the reaction. The catalyst provides an alternate reaction mechanism that increases the proportion of collisions at a lower temperature, thereby decreasing the amount of energy needed to complete the reaction. The catalyst may participate in multiple chemical transformations, however it is unchanged at the completion of the reaction and can be recycled and reused.
The reaction on the catalyst surface begins with adsorption of the reagents to the active site, followed by the reaction on the surface. The surface reaction can occur between one adsorbed species and one in the bulk, called the Eley-Rideal mechanism, or between two adsorbed species, called the Langmuir-Hinshelwood mechanism. The products then desorb from the surface into the bulk.
Now that you understand the basics of catalysis, let's look at the reduction of 4-nitrophenol to 4-aminophenol using a commercially available palladium catalyst supported on ground active carbon. The reaction progress will be measured using the color change that occurs during the reaction.
Before beginning the experiment, be sure to wear appropriate personal protective equipment, such as a lab coat, safety goggles, and gloves. To prepare the materials, first weigh 14 mg of 4-nitrophenol and dissolve it in 10 mL of deionized water in a glass vial to make a 10 mM solution. Next, weigh 57 mg of sodium borohydride and dissolve it in 15 mL of DI water to make a 100 mM solution. Mix the two, and stir at room temperature to form a uniform solution. The solution color should not change, as the sodium borohydride cannot fully reduce 4-nitrophenol without the catalyst. Weigh 10 mg of palladium on active carbon and 10 mg of active carbon without catalyst as a control sample.
Transfer the weighed catalysts into separate vials, and add 100 mL of deionized water to each. Sonicate the vials with an output power of 135 Watts until catalysts are well distributed in the water.
Now that the materials are prepared, the catalytic reduction of 4-nitrophenol can be performed. Measure 1.15 mL of the prepared 4-nitrophenol and sodium borohydride solution, and transfer to a 5-mL glass vial.
Observe and record the color of the solution in the vial. Add 1 mL of the prepared palladium on active carbon catalyst solution to the vial, and shake by hand to mix.
Observe the reaction for 20 min, and record when the solution color begins to change and then completely fades. When all of the color has faded, the reaction is complete.
Repeat the same procedure for the active carbon control solution. As the reaction progresses, the color changes from yellow to colorless, indicating the consumption of 4-nitrophenol. To quantify this change, measure UV-Vis absorbance of the sample at 400 nm.
Plot the natural log of absorbance versus time. The absorbance decreases over the course of the reaction, indicating the consumption of 4-nitrophenol. The control sample showed no catalytic activity.
Catalysts are of vital importance to a wide range of industrial and scientific fields.
In the presence of a palladium catalyst, carbon-carbon coupling reactions occur, known as the Heck Reaction. The Heck reaction is regarded as the first correct mechanism for transition metal-catalyzed coupling reactions. It is so valuable to modern catalysis that Richard F. Heck received the Nobel Prize in Chemistry for his discovery. The Heck Reaction can be performed using a palladium catalyst, as shown in this experiment. Here, the catalyst was synthesized at room temperature. After the reaction, the product was analyzed using nuclear magnetic resonance spectroscopy, or NMR.
In nature, enzymes are catalysts that enable a wide range of biological reactions. For example, acetate kinase is an enzyme found in microorganisms that facilitates the reversible conversion of acetate to acetyl phosphate.
The enzyme activity was measured using UV-Vis spectrophotometry, with a standard curve.
The amount of acetyl phosphate consumed was monitored throughout the reaction, and the enzyme kinetics plotted as a function of time.
Polymers are another field that can take advantage of catalysis. Here, star-shaped polymer particles were synthesized.
First, the catalyst was prepared and dried at room temperature. The polymer branches were then mixed with the catalyst, and then a cross-linker was added to form the particles.
The particle size was then analyzed using gel permeation chromatography. Polymeric nanoparticles, like the star polymers fabricated in this example, are used for a wide range of applications such as drug delivery and self-assembly.
You've just watched JoVE's Introduction to catalysis. After watching this video, you should understand the concept of catalysis and how to run a simple reaction in the laboratory.
Thanks for watching!
The reduction of 4-nitrophenol with a catalyst is a benchmark reaction in the literature for evaluating catalyst performance and measuring kinetics. Prior to the addition of catalyst, the color of the solution is light yellow, which corresponds to the 4-nitrophenol ion in alkaline conditions. Without the addition of a catalyst, the yellow color does not fade away, this indicates that the mixture system of 4-nitrophenol and sodium borohydride is stable.
After the addition of palladium on active carbon and palladium on granular carbon catalyst solutions, the yellow color of 4-nitrophenol solution gradually fades. At a time scale of approximately 20 min, the solution becomes colorless, suggesting a complete reduction of 4-nitrophenol by the catalyst.
After the addition of the active carbon solution, with no catalyst, the yellow color of 4-nitrophenol remains unaltered within the 20-min reaction window. Carbon acts only as a support material for palladium, so carbon by itself does not demonstrate any catalytic effect on the reaction. The control group here shows that nanoscale palladium particles supported on carbon is an active catalyst while the carbon itself is not a catalyst. This control experiment also shows that the 4-nitrophenol is not simply absorbed by the carbon and removed from the solution.
Observation of the UV-Vis absorption spectra indicates a gradual decrease at around 400 nm while increasing at around 300 nm. This change is indicative of the reduction of 4-nitrophenol during the process. The relative concentration of 4-nitrophenol is represented by the relative intensity of the absorption at 400 nm. A plot ln(At/A0) vs. time shows the reaction proceeding in a quantified way. A representative plot is shown in Figure 1.
Figure 1. Plot of absorption vs. time during the reduction of 4-nitrophenol by the palladium catalyst on active carbon.
For both palladium catalysts used, there is no difference between their color change behavior and their spectra. This result indicates palladium is active in catalytic reduction of 4-nitrophenol regardless of whether it is supported on active carbon or granular carbon.
As a benchmark reaction, the catalytic application of nanoscale palladium particles can be extended to other fields. Similar to the reduction of 4-nitrophenol, which is a colorometric (the reaction is observed as a color change), the hydrogenation of chemical dyes can be accomplished with the same protocol. Chemical hydrogenation processes are very important in many industrial reactions as well as waste disposal. Researchers have found applications of catalysts in hydrogenation reactions in fields such as petrochemicals. In the United States, benzene production reached 415,144 million gallons during fourth quarter in 2010, where hydrogenation process played an important role.
In the presence of a palladium catalyst and a basic environment, C-C coupling reactions occur between aryl/vinyl halides and alkenes.3,4 This reaction is known as the Heck Reaction. C-C coupling reactions are of vital importance to solving the energy challenges now facing society. The implication is so important that the 2010 Nobel Prize in chemistry was awarded for work on palladium catalyzed cross coupling reaction. Catalysts are also used in the synthesis of polymer nanoparticles. In this application, polymer branches are mixed with a catalyst in order to induce the formation of star particles.5 Finally, catalysts are found widely in nature, and drive biological reactions. Here, they naturally exist as shape specific enzymes.6
Catalysts are substances that are added to chemical systems to enable chemical reactions to occur faster, using less energy.
The minimum amount of energy required to initiate a reaction is called the activation energy. Catalysts provide an alternate reaction pathway with a lower activation energy, allowing the reaction to take place under less extreme conditions. The activation energy is described by the Arrhenius equation.
Enzymes are biological molecules that behave as extremely specific catalysts. Enzymes are shape specific, and guide reactant molecules, called substrates, into the optimal configuration for reaction. Homogeneous catalysts are in the same phase as the reactants. Most frequently, the catalyst and reactants are both dissolved in the liquid phase. In heterogeneous catalysis, the catalyst and reactants are in different phases, separated by a phase boundary. Commonly, heterogeneous catalysts are solid and consist of a nano-scale catalytic entity, typically a metal nanoparticle, which is dispersed on a support material.
The support material, usually carbon, silica, or a metal oxide, is used to increase the surface area and impart stability against aggregation of the nanoparticles. Porous membranes and beads, mesh, and stacked sheets are some of the support geometries used in catalysis.
In heterogeneous catalysis, nanoparticles have active sites on the surface, where the reaction takes place. Depending on the reaction, these active sites could be planar faces or crystal edges on the surface of the particle. Typically, smaller nanoparticles have higher catalytic activity, due to the higher amount of surface atoms per mole of catalyst.
This video will highlight the basics of catalysis, and demonstrate how to perform a basic catalytic reaction in the laboratory.
There are several types of catalysts. At high temperature, molecules move faster and collide more frequently. Since the proportion of molecular collisions is higher, the reactants have enough energy to overcome the activation energy of the reaction. The catalyst provides an alternate reaction mechanism that increases the proportion of collisions at a lower temperature, thereby decreasing the amount of energy needed to complete the reaction. The catalyst may participate in multiple chemical transformations, however it is unchanged at the completion of the reaction and can be recycled and reused.
The reaction on the catalyst surface begins with adsorption of the reagents to the active site, followed by the reaction on the surface. The surface reaction can occur between one adsorbed species and one in the bulk, called the Eley-Rideal mechanism, or between two adsorbed species, called the Langmuir-Hinshelwood mechanism. The products then desorb from the surface into the bulk.
Now that you understand the basics of catalysis, let’s look at the reduction of 4-nitrophenol to 4-aminophenol using a commercially available palladium catalyst supported on ground active carbon. The reaction progress will be measured using the color change that occurs during the reaction.
Before beginning the experiment, be sure to wear appropriate personal protective equipment, such as a lab coat, safety goggles, and gloves. To prepare the materials, first weigh 14 mg of 4-nitrophenol and dissolve it in 10 mL of deionized water in a glass vial to make a 10 mM solution. Next, weigh 57 mg of sodium borohydride and dissolve it in 15 mL of DI water to make a 100 mM solution. Mix the two, and stir at room temperature to form a uniform solution. The solution color should not change, as the sodium borohydride cannot fully reduce 4-nitrophenol without the catalyst. Weigh 10 mg of palladium on active carbon and 10 mg of active carbon without catalyst as a control sample.
Transfer the weighed catalysts into separate vials, and add 100 mL of deionized water to each. Sonicate the vials with an output power of 135 Watts until catalysts are well distributed in the water.
Now that the materials are prepared, the catalytic reduction of 4-nitrophenol can be performed. Measure 1.15 mL of the prepared 4-nitrophenol and sodium borohydride solution, and transfer to a 5-mL glass vial.
Observe and record the color of the solution in the vial. Add 1 mL of the prepared palladium on active carbon catalyst solution to the vial, and shake by hand to mix.
Observe the reaction for 20 min, and record when the solution color begins to change and then completely fades. When all of the color has faded, the reaction is complete.
Repeat the same procedure for the active carbon control solution. As the reaction progresses, the color changes from yellow to colorless, indicating the consumption of 4-nitrophenol. To quantify this change, measure UV-Vis absorbance of the sample at 400 nm.
Plot the natural log of absorbance versus time. The absorbance decreases over the course of the reaction, indicating the consumption of 4-nitrophenol. The control sample showed no catalytic activity.
Catalysts are of vital importance to a wide range of industrial and scientific fields.
In the presence of a palladium catalyst, carbon-carbon coupling reactions occur, known as the Heck Reaction. The Heck reaction is regarded as the first correct mechanism for transition metal-catalyzed coupling reactions. It is so valuable to modern catalysis that Richard F. Heck received the Nobel Prize in Chemistry for his discovery. The Heck Reaction can be performed using a palladium catalyst, as shown in this experiment. Here, the catalyst was synthesized at room temperature. After the reaction, the product was analyzed using nuclear magnetic resonance spectroscopy, or NMR.
In nature, enzymes are catalysts that enable a wide range of biological reactions. For example, acetate kinase is an enzyme found in microorganisms that facilitates the reversible conversion of acetate to acetyl phosphate.
The enzyme activity was measured using UV-Vis spectrophotometry, with a standard curve.
The amount of acetyl phosphate consumed was monitored throughout the reaction, and the enzyme kinetics plotted as a function of time.
Polymers are another field that can take advantage of catalysis. Here, star-shaped polymer particles were synthesized.
First, the catalyst was prepared and dried at room temperature. The polymer branches were then mixed with the catalyst, and then a cross-linker was added to form the particles.
The particle size was then analyzed using gel permeation chromatography. Polymeric nanoparticles, like the star polymers fabricated in this example, are used for a wide range of applications such as drug delivery and self-assembly.
You’ve just watched JoVE’s Introduction to catalysis. After watching this video, you should understand the concept of catalysis and how to run a simple reaction in the laboratory.
Thanks for watching!