EXPERIMENTAL AND THEORETICAL STUDIES ON GLUCOSE HYDROGENATION TO PRODUCE SORBITOL M.Banu (26-09-2009) Marcia C. Martins Castoldi, React.Kinet.Catal.Lett.

Slides:



Advertisements
Similar presentations
Chemistry 2100 Lecture 9.
Advertisements

IMPORTANT FUNCTIONS OF CARBOHYDRATES To provide energy through their oxidation To supply carbon for the synthesis of cell components To serve as a stored.
Chapter 17: Carbohydrates
Carbohydrate chemistry Definition Nomenclature Cyclic form of sugar Optical isomerism Glycosidic link Polysaccharides Carbohydrate derivatives.
 Types of Carbohydrates  Classification of Monosaccharides  D and L Notations from Fischer Projections  Structures of Some Important Monosaccharides.
Catalysts Learning intention Learn how a catalyst speeds up reaction rate by lowering the activation energy, and how to represent this on a potential energy.
Introduction to catalysis chemistry
Unit 1: Biochemistry Part III: Organic Chemistry Carbohydrates.
Chapter Eighteen Carbohydrates Ch 18 | # 2 of 52 Carbohydrates cont’d.
1 A Density Functional Study of the Competing Processes Occuring in Solution during Ethylene Polymerisation by the Catalyst (1,2Me 2 Cp) 2 ZrMe + Kumar.
Case Western Reserve University
Chapter 16 Carbohydrates
Carbohydrates What are they? –Sugars, starches & much more –Most abundant molecules on Earth –End products of photosynthesis.
Lab 5: Qualitative Analysis Test for Carbohydrates
1 Carbohydrates Classification Monosaccharides Chiral Carbon Atoms Structures of Important Monosaccharides Cyclic Structures.
CHAPTER 15 Carbohydrates. Where in the world do we find carbohydrates? Most abundant organic compound in nature Photosynthesis: plants make glucose using.
CLS 101: Chemistry for Nursing
Calcium carbonate (marble) hydrochloric acid carbon dioxide.
Carbohydrate Structure
Writing Equations for Organic Reactions
1 Li Xiao and Lichang Wang Department of Chemistry & Biochemistry Southern Illinois University Carbondale The Structure Effect of Pt Clusters on the Vibrational.
Chapter 25 Biomolecules: Carbohydrates. 2 The Importance of Carbohydrates Carbohydrates are… –widely distributed in nature. –key intermediates in metabolism.
Alcohols. Alcohols are saturated hydrocarbons in which one or more of the hydrogen atoms are replaced by OH group.
Theoretical Study of Photodissociation dynamics of Hydroxylbenzoic Acid Yi-Lun Sun and Wei-Ping Hu* Department of Chemistry and Biochemistry, National.
Biochemistry Unit.  Composed of carbon, hydrogen, and oxygen in a 1:2:1 ratio.  The basic unit is called a monosaccharide and includes glucose, fructose,
By: Debbie Schwagerman January 31, Atomic Bonds and Molecular Interactions Each atom has a defined number and geometry of covalent bonds. Each atom.
A catalyst is a chemical agent that changes the rate of a reaction without being consumed by the reaction. An enzyme is a protein. 1. Enzymes speed up.
CARBOHYDRATES Carbohydrates are a major energy source for living organisms Carbohydrates always have a 1:2:1 ratio of carbon, hydrogen, and oxygen. Mitochondria.
Carbohydrates. Structure and Function How do we define a carbohydrate? aldehydes or ketones with multiple hydroxyl groups “hydrate” of carbon – C-H 2.
Oxidation of Carbohydrates Most living organisms that live in air obtain energy by oxidation of carbohydrates. Glucose is the most common simple carbohydrate.
Carbohydrates. Introduction: Carbohydrates are the most abundant organic compounds in the plant world They are storehouses of chemical energy (glucose,
Chapter 18: Carbohydrates
Heterocyclic Chemistry Chapter 5 Carbohydrates. Heterocyclic Chemistry Biological importance  Carbohydrates are compounds of tremendous biological importance:
1 Chapter 13: Carbohydrates Chem 20 El Camino College.
17.5 Properties of Monosaccharides
Chapter 7.1: Monosaccharides and Disaccharides
Chapter 16 Aldehydes and Ketones Nucleophilic Addition to the Carbonyl Group.
Chapter 20 Carbohydrates. Carbohydrates Carbohydrate: Carbohydrate: A polyhydroxyaldehyde or polyhydroxyketone, or a substance that gives these compounds.
ChE 553 Lecture 29 Catalysis By Metals 1. Objective Apply what we have learned to reactions on metal surfaces 2.
Carbohydrates Carbohydrate: A compound with multiple hydroxy and/or carbonyl groups that has the general formula C x (H 2 O) y ; a hydrate of carbon. The.
Structures of Aldehydes and Ketones Both aldehydes and ketones contain a carbonyl group Aldehydes have at least one H attached, while ketones have two.
Chapter 7 Carbohydrates.
Chapter 6 The Chemistry of Life. Atoms and their interactions.
Electronic Structure and Chemical Reactivity
Organic Chemistry. Homologous Series A grouping of organic compounds based on their composition and properties A series has: A general formula The same.
Chapter 11 Outline 11.1 Alcohols, Ethers, and Related Compounds
Accumulation of trans FA is an indication that hydrogenation is not proceeding to completion in the rumen. Accumulation of C18:2 bloks conversion of Trans-C18-1.
Chapter 7: Carbohydrates “Sugars” –Nutrient source (energy source) –Structural component Eg. cellulose (pure polymeric sugar) Or in combination with peptides.
Chapter 20: Carbohydrates Carbohydrate: Carbohydrate: A polyhydroxyaldehyde or polyhydroxyketone, or a substance that gives these compounds on hydrolysis.
Elements Pure substances that cannot be broken down chemically into simpler kinds of matter More than 100 elements (92 naturally occurring)
Chemistry of Carbohydrates
Catalytic production of methane from CO 2 and H 2 at low temperature: Insight on the reaction mechanism A review by Shujin Jiang 3/17/2015.
CARBOHYDRATES Carbohydrates.
Carbohydrate Structure and the Glycosidic Bond
ChE 551 Lecture 29 Catalysis By Metals.
A DFT study of CO and H2 dissociation over MoP surfaces
Lecture 4 More Sugars: Disaccharides and Rings
Carbohydrates.
AN INTRODUCTION TO METABOLISM
Carbohydrates Dr. Gamal Gabr.
LincoLarry Jln High School
15.3 Haworth Structures of Monosaccharides
Lecture 2: Monosaccharides
The Organic Chemistry of Carbohydrates
3.2 MONOSACCHARIDES.
AN INTRODUCTION TO METABOLISM
AN INTRODUCTION TO METABOLISM
Carbohydrates Carbohydrate: a polyhydroxyaldehyde or polyhydroxyketone, or a substance that gives these compounds on hydrolysis Monosaccharide: a carbohydrate.
AN INTRODUCTION TO METABOLISM
Presentation transcript:

EXPERIMENTAL AND THEORETICAL STUDIES ON GLUCOSE HYDROGENATION TO PRODUCE SORBITOL M.Banu ( ) Marcia C. Martins Castoldi, React.Kinet.Catal.Lett. Vol. 91, No. 2, 341−352 (2007)

 Sorbitol and mannitol are highly important chemical compounds as they can be used in several industrial applications.  Approximately 60% of the available sorbitol is used as additive in foods, medicines, cosmetics and toothpastes.  The industrial production of sorbitol and mannitol consists in the catalytic hydrogenation of sucrose, glucose or fructose  The Raney-Ni type catalyst has been employed in this process due to its high activity and low cost  However, ruthenium catalysts present higher activity than nickel in the hydrogenation of glucose in aqueous solutions INTRODUCTION

Mechanism for glucose and fructose hydrogenation  The surface of the catalyst may possess two types of sites, an acidic (the metal) and a basic one (the support), it may be rationalized that the saccharide adsorbs on the acidic sites through the C=O bond while the dissociative adsorption of hydrogen occurs in the basic sites  The interaction between the adsorbed composites leads to the final product sorbitol.

 Basically, the monosaccharide family may consist of polyhydroxy aldehydes or ketones, i.e., aldoses or ketoses.  In solution these compounds cyclize to produce five- and/or six- membered rings (furanoses and pyranoses, respectively), which are much more stable than their open chain counterparts  Depending on the position of the OH group at the C1 atom, there are two stereochemical species (anomers) for a pyranose or furanose. The anomers are termed α and β when the OH group at C1 is below or above the ring plane of the Haworth formula, respectively. Each of them having characteristic hydrogenation rates  Based on those rates, it can be determined which anomer is preferentially adsorbed and hydrogenated With this goal, the joint utilization of experimental and theoretical methods provides feasible tools to study the structural and molecular properties in chemical systems.

Quantum calculations  In the first stage of the quantum study a conformational analysis of the α and β anomers of glucose with the semi-empirical AM1 (Austin model 1) method was carried out  The most stable confirmation in each case was re-optimised using the DFT methodology with the B3LYP functional and the D95V basis set  In the second stage the optimized geometry of the most stable α anomer, was then adsorbed on a metallic cluster of Ru 4 and Pt 4  The metallic clusters, in a planar arrangement, were maintained fix at their initial arrangement, with Ru-Ru distances of 2.70A and Pt-Pt distances of 2.77A while the sugar structure was fully optimized  For calculation of the sugar-metal interaction the D95V basis set for the sugar and the LANL2DZ pseudopotential for the metal were employed  The interaction energy is calculated as the difference between the energy of the sugar- metal complex, and the energy of the sugar and the metallic clusters calculated at infinite separation

CatalystTemperature( 0 C)Pressure(atm)Conversion(%) 10% Pt/C % Ru/C % Ru/C10080bar99 10%Ru-Pt/C10080bar15 Experimental conditions used in the hydrogenation reactions Catalyst: Pt/C, Ru/C, Ru-Pt/C Reactor: 100 ml parr reactor Reactant: 50% glucose solution Product analysis: HPLC

The most stable conformations of the glucose molecule and their respective heat of formation calculated with the semi-empirical AM1 method  Pyranose structures are more stable than the corresponding furanose ones, since pyranoses have been found to predominate at equilibrium conditions in solution.  Da Silva et al. concluded that glucose occurs in aqueous solution with more than 99% as a six- membered pyranosic ring.  Once the α-pyranose anomer was identified as being the most stable form, it was taken for the interaction studies with the metallic clusters.  However, in order to eliminate any deficiency of the semi-empirical AM1 method, the two most stable conformations of the α-pyranose anomer were re-optimized at the B3LYP/D95V level.  The essential difference between these two conformations is that in one of them the hydroxyl groups are oriented clockwise, while, in the other one, they are oriented in a counter-clockwise way.  For the isolated molecule, the hydroxyls prefer to be oriented in a way to yield a cooperative hydrogen bonding chain that is as efficient as possible.  For a glucopyranose the counterclockwise conformation is 0.87 kcal/mol more stable than the corresponding clockwise conformation.

Interaction studies with the metallic surfaces  In the first stage the calculations were carried out for a fixed geometry of the M4 clusters (M = Ru or Pt). Changing the multiplicity of the metallic clusters allows us to determine its electronic state of lower energy.  The data indicate that the lowest energy state for the Pt4 cluster is that with multiplicity 5 (S=2), while for the Ru4 cluster the lowest energy state is obtained with multiplicity 13 (S=6). Geometric parameters for the metallic clusters

E ADS = adsorption energy E Glucose/Cluster = energy of glucose adsorbed on the metallic cluster E glucose E cluster =energies of the glucose molecule and of the cluster individually, meaning at infinite separation The adsorption energy of glucose on Ru 4 is 12.4 kcal/mol The adsorption energy of glucose on Pt 4 is 18.3 kcal/mol

 The parameter more intimately related to the efficiency of a catalyst should therefore be its capacity to promote changes in the geometry, which may at the end lead to a reduction in the activation barrier for the reaction in the rate determining step.  In this way the geometric changes that occur upon glucose adsorption may have stronger influence on the reaction profile, especially if changes in bond lengths close to the contact point with the metal are observed.  In this respect changes in some C-O bond lengths are noteworthy. The C2-O1 bond in the isolated glucose molecule has a length of 1.44 Ǻ. It increases to 1.47 Ǻ after adsorption, a clear indication that the process of adsorption weakens this bond, consequently reducing the energy necessary to break it.  These results show that by adsorption the anomeric carbon becomes more susceptible to attack by hydrides.  For the case of platinum, small changes in the bonds length of the glucose molecule had been observed, but these changes were not significant as compared with the changes promoted by the ruthenium cluster.

CONCLUSIONS  The conformational analysis of the glucose molecule shows that the α-pyranose anomer is the most stable one.  After optimization, the most stable conformation is that with the hydroxyl groups oriented counter-clockwise.  This is 3.88 kcal/mol more stable than the corresponding anomer in the clockwise orientation.  The admixture of ruthenium and platinum catalyst supported on carbon (Ru-Pt/C) presents conversion lower than 50% showing that platinum reduces the performance of ruthenium.  The calculations show that glucose adsorbs more intensely on a Pt 4 cluster than on Ru 4. However, geometric changes observed after adsorption on Ru 4 indicate that it may promotes the break of the C 2 -O 1 bond, thereby, facilitating the attack by hydrides.