EFFICACY OF THE BLEND OF EXTRACTS FROM AFZELIA AFRICANA, BRACHYSTEGIA EURYCOMA AND MOMORDICA CHARANTIA SEEDS FOR CORROSION INHIBITION OF MILD STEEL IN 1M HCL SOLUTION

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ABSTRACT

The efficacy of blend of Afzelia africana (AA), Brachystegia eurycoma (BE) and Momordica charantia (MC) seed extracts was investigated as a cheap and ecologically friendly alternative mild steel corrosion inhibitor. The experimental aspect of the corrosion inhibition process was carried out in 1.0 M hydrochloric acid at temperatures ranging from 303K to 343K and concentration range of 0.1 to 0.5 g/L using Phytochemical Screening, gravimetric/weight loss, thermometric and hydrogen evolution techniques. The surface characterization was done using scanning electron microscopy (SEM) and Fourier transform infrared spectroscopic (FTIR) techniques. The theoretical aspect was studied using the density functional theory calculations and modeling of the electronic structures of some of the most effective extract constituents, including physisorptive interactions with the mild steel surface. The inhibition efficiency was determined by comparison of the corrosion rates in the absence and presence of the seed extracts. The inhibition efficiency increases gradually in the order: blend > AA > BE > MC with the blend reaching a maximum value of 95.4% within the first 60 minutes of exposure at a concentration of 0.5 g/L and temperature of 303K. The inhibition efficiencies by both the hydrogen evolution and thermometric methods when compared with that obtained by weight loss method, followed the same trend. The adsorption parameters showed that the Freundlich isotherm was the best model for the individual seed extracts and the modified Langmuir adsorption isotherm for the blend. The kinetic study shows that the inhibitory action follows a first order kinetics with the concentration of both the individual seed extracts and their blends. This was further supported by the thermodynamic parameters which reveal that the adsorption of both the individual seed extracts and their blends onto the metal surface was spontaneous, endothermic and followed physical adsorption mechanism. The low values of adsorption equilibrium constant, Kads indicate low interaction between the adsorbed molecules and the metal surfaces which further confirmed that the extracts were physically adsorbed onto the metal surface. FTIR study of the blended seed extracts and the corrosion product of mild steel showed an interaction between the inhibitor and the metal surface. SEM analyses of the corrosion product also confirmed the formation of a protective layer on the surface of the metal. Quantum chemical studies indicated that inhibition was due to adsorption of active molecules leading to formation of a protective layer on surface of mild steel. Quantum chemical parameters such as highest occupied molecular orbital (HOMO), lowest unoccupied molecular orbital (LUMO) energy levels, HOMO–LUMO energy gap and electronic density were virtually identified. Therefore, the inhibition of mild steel corrosion is proposed to occur through synergistic combination of the constituents of the inhibitor, which leads to the formation of inhibitor-metal complex and subsequent protection of the metal from further corrosion attack.

TABLE OF CONTENTS

Cover page i

Title Page ii

Declaration iii

Certification iv

Dedication v

Acknowledgement vi

Table of Contents vii

List of Tables xiii

List of Figures xvi

List of Plates xxiv

Abstract xxv

1.0 Chapter 1: Introduction 1

1.1 Background of Study 1

1.2 Statement of the problem 4

1.3 Aim of the Study 5

1.4 Objectives of the Study 5

1.5 Significance of the Study 6

1.6 Scope of the Study 6

1.7 Justification of the Study 7

2.0 Chapter 2: Literature Review 8

2.1 Corrosion 8

2.2 Corrosion Chemistry 9

2.3 Classification of Corrosion 11

2.3.1 Dry Corrosion 11

2.3.2 Wet Corrosion 11

2.4 Forms of Corrosion 11

2.4.1 Uniform Corrosion 12

2.4.2 Galvanic or Two Metal Corrosion 12

2.4.3 Carbon dioxide Corrosion 13

2.4.3.1 Pitting Corrosion 13

2.4.3.2 Mesa-Type Attack 14

2.4.3.3 Flow-Induced Localized Corrosion 14

2.4.4 Crevice Corrosion 14

2.4.5 Intergranular Corrosion 14

2.4.6 Selective Leaching 15

2.4.7 Erosion Corrosion 15

2.4.8 Stress Corrosion 16

2.5 Factors Affecting Corrosion 16

2.6 The Problem of Corrosion 17

2.7 Corrosion Control 18

2.7.1 Materials selection and design 19

2.7.2 Surface Coatings 19

2.7.3 Modification of the Electrolyte 20

2.7.3.1 Removal of the Aggressive Species 20

2.7.3.2 The Addition of Corrosion Inhibitors 20

2.8 Types of Corrosion Inhibitors 21

2.8.1 Organic Inhibitors 21

2.8.1.1 Synthetic Organic Inhibitors 22

2.8.1.2 Natural Organic Inhibitors 23

2.8.2 Inorganic Inhibitors 24

2.8.2.1 Anodic Inhibitors 24

2.8.2.2 Cathodic Inhibitors 26

2.9 Corrosion Monitoring Techniques 27

2.9.1 Weight loss method 27

2.9.2 Gasometric/Hydrogen Evolution Method 28

2.9.3 Thermometric Method 30

2.10 Plant Description 31

2.10.1 Afzelia Africana (AA) 31

2.10.2 Brachystegia Eurycoma (BE) 32

2.10.3 Momordica Charantia (MC) 33

2.11 Methods Used For Extraction Of Plant Materials 35

2.12 Phyto-Chemical Analysis as a Tool in Corrosion Inhibition 36

2.13 Adsorption Isotherm 38

2.13.1 Langmuir Adsorption Isotherm 40

2.13.2 Temkin Adsorption Isotherm 42

2.13.3 Freundlich Adsorption Isotherm 43

2.13.4 Choice of Appropriate Adsorption Isotherm Model 44

2.14 Determination of Associated Thermodynamic and Kinetic Parameters 44

2.14.1 Thermodynamic Considerations 44

2.14.2 Kinetic Considerations 46

2.14.2.1Effect of Concentration on Reaction Rate 46

2.14.2.2Effect of Temperature on Reaction Rate 48

2.15 Theoretical and Quantum Chemical Studies as a Corrosion Monitoring Techniques 49

2.16 Scanning Electron Microscopy (SEM) 54

2.17 Empirical Review 56

2.17.1 Effects of Concentration on Corrosion Inhibition 56

2.17.2 Effect of Immersion Time on Corrosion Inhibition 61

2.17.3 Effect of Temperature on Corrosion Inhibition 64

2.18 Adsorption Isotherm Studies 68

2.19 Thermodynamics and Kinetic Treatment 71

2.20 Quantum Chemical Studies 76

3.0 Chapter 3: Methodology 79

3.1 Materials and Methods 79

3.1.1 Materials 79

3.2 Experimental Procedure 80

3.2.1 Preparation of Specimen 80

3.2.2 Surface Area and density of specimen 80

3.2.3 Preparation of Blends of Afzelia Africana, Brachystegia Eurycoma and

Momordica Charantia seed extracts 81

3.2.4 Preparation of 1.0M HCl 82

3.3 Phyto-Chemical Analysis 83

3.3.1 Test for Alkaloids 84

3.3.2 Test for Saponins 84

3.3.3 Test for Tannins 84

3.3.4 Test for Phenol 84

3.3.5 Test for Flavonoids 84

3.3.6 Test for Glycosides 84

3.3.7 Test for Steroids 85

3.3.8 Test for carbohydrates 85

3.3.9 Test for Reducing Sugar 85

3.3.10 Test for Proteins 85

3.3.11 Test for Amino acids 86

3.4 Gravimetric Technique 86

3.5 Hydrogen Evolution (Gasometric) Method 88

3.6 Thermometric Method 88

3.7 Adsorption Isotherm Study 89

3. 7.1 Langmuir Adsorption Isotherms 89

3.8 Thermodynamic and Kinetic Studies 90

3.8.1 Standard Gibbs free energy change of Adsorption, ΔG°_ads 90

3.8.2 Activation Energy, E_a 90

3.8.3 Rate Constant for the Corrosion Rate, k 91

3.8.4 Half-life, t_1/2 91

3.9 Scanning Electron Microscopy (SEM) 91

3.10 Fourier Transform Infrared Spectroscopy (FTIR) 91

3.11 Theoretical and Quantum Chemical Calculations 92

4.0 Chapter 4: Results and Discussion 93

4.1 Elemental Composition of Mild Steel 93

4.2 Phytochemical Screening 94

4.3 Weight Loss Results 97

4.3.1 Effect of Concentration of extracts on Corrosion Rate and Inhibition Efficiency 99

4.3.2 Effect of Immersion Time on Corrosion Inhibition 104

4.3.3 Effect of Temperature on Corrosion Rate and Inhibition Efficiency 106

4.4 Gasometric Results 111

4.5 Thermometric Results 116

4.6 Adsorption Mechanism 118

4.7 Thermodynamic and Kinetic parameters for the corrosion inhibition of both the

individual seed extracts and their Blends 128

4.7.1 Standard Gibbs free energy of adsorption, ΔG°_ads 129

4.7.2 Activation Energy (E_a)for the Corrosion Process 130

4.7.3 Activation Parameters for the Corrosion Process 132

4.7.4 Rate of Reaction and Rate Constant of the Reaction 134

4.7.5 Half Life 147

4.8 Surface Studies by Scanning Electron Microscopy 149

4.9 Fourier transform infrared spectroscopy (FTIR) analysis 151

4.10 Theoretical and Quantum Chemical Studies 155

4.10.1 Mulliken charge distribution of Glucose, Arginine, Flavonol and Leucine 163

5.0 Chapter 5: Conclusion and Recommendations 166

5.1 Conclusion 166

5.2 Recommendations 168

References 169

Appendixes 183

LIST OF TABLES

3.1 List of Materials Used for the Experiments 79

3.2 List of Equipment for the Experiments 80

4.1 Elemental composition of mild steel employed in the study 93

4.2 Phytochemical Constituent of blends of AA, BE and MC extract 94

4.3 Hydrogen evolution data for mild steel corrosion in 1 M HCl solution in the absence and presence of the blended seed extract 111

4.4 Thermometric data for mild steel in 1.0 M HCl solution in the absence and presence of blended seed extract (AA, BE and MC) 116

4.5 Isotherm parameters for the adsorption of ethanolic extract of Afzelia africana seed

on the surface of mild steel in HCl 118

4.6 Isotherm parameters for the adsorption of ethanolic extract of Brachystegia eurycoma

seed on the surface of mild steel in HCl 120

4.7 Isotherm parameters for the adsorption of ethanolic extract of Momordica charantia

seed on the surface of mild steel in HCl 122

4.8 Isotherm parameters for the adsorption of ethanolic extracts of the blends of Afzelia africana, Brachystegia eurycoma and Momordica charantia seeds on the surface of

mild steel in HCl 124

4.9 Calculated values of thermodynamic and kinetic parameters for mild steel corrosion in

1 M HCl in the absence and presence of Afzelia africana seed extract as inhibitor 128

4.10 Calculated values of thermodynamic and kinetic parameters for mild steel corrosion in

1 M HCl in the absence and presence of Brachystegia eurycoma seed extract as

inhibitor 128

4.11 Calculated values of thermodynamic and kinetic parameters for mild steel corrosion in

1 M HCl in the absence and presence of Momordica charantia seed extract as

inhibitor 128

4.12 Calculated values of thermodynamic and kinetic parameters for mild steel corrosion in

1 M HCl in the absence and presence of blended seed extracts as inhibitor 129

4.13 Calculated values of the rate constant for mild steel corrosion in 1 M HCl in the absence

and presence of Afzelia africana seed extract 141

4.14 Calculated values of the rate constant for mild steel corrosion in 1 M HCl in the absence

and presence of Brachystegia eurycoma seed extract 141

4.15 Calculated values of the rate constant for mild steel corrosion in 1 M HCl in the absence

and presence of Momordica charantia seed extract 142

4.16 Calculated values of the rate constant for mild steel corrosion in 1 M HCl

in the absence and presence of blended seed extracts 143

4.16 Calculated values of the half life for mild steel corrosion in 1 M HCl in the absence

and presence of Afzelia africana seed extract 147

4.17 Calculated values of the half life for mild steel corrosion in 1 M HCl in the absence

and presence of Brachystegia eurycoma seed extract 147

4.18 Calculated values of the half life for mild steel corrosion in 1 M HCl in the absence

and presence of Momordica charantia seed extract 148

4.19 Calculated values of the half life for mild steel corrosion in 1 M HCl in the absence

and presence of blended seed extracts 148

4.21 IR Absorption of Afzelia africana seed extract 151

4.22 IR Absorption of Brachystegia eurycoma seed extract 151

4.23 IR Absorption of Momordica charantia seed extract 151

4.24 Quantum chemical parameters for most important components of the ethanol extract

of Blend of AA, BE and MC 155

4.25 Mulliken Charge Distribution on Flavonol, Leucine, Arginine and Glucose 165

LIST OF FIGURES

2.1 Anodic Inorganic Inhibitors Effect and their Mechanism of Action 25

2.2 Mechanism of Actuation of the Cathodic Inhibitors 26

2.3 Gasometric assembly for measurement of hydrogen gas evolved 29

2.4 Extraction method used for preparation of plant extracts 36

2.5 Schematic representation of an adsorption isotherm 39

4.1 Structures of the Phytochemicals Present in the blended seed extracts 95

4.2 Variation of weight loss with time for mild steel coupons in 1 M HCl solutions

containing Afzelia africana at 303K 97

4.3 Variation of weight loss with immersion time for mild steel coupons in 1 M HCl

solutions containing Brachystegia eurycoma at 303K 97

4.4 Variation of weight loss with immersion time for mild steel coupons in 1 M HCl

solutions containing Momordica charantia at 303K. 97

4.5 Variation of weight loss with immersion time for mild steel coupons in 1 M HCl

solution containing the Blend at 303K 98

4.6 Variation of corrosion rate with concentration of Afzelia africana extract for mild steel coupons in 1 M HCl solution at different time intervals at 303 K 99

4.7 Variation of corrosion rate with concentration of Brachystegia eurycoma extract for

mild steel coupons in 1 M HCl solution at different time intervals at 303 K 99

4.8 Variation of corrosion rate with concentration of Momordica charantia extract for mild

steel coupons in 1 M HCl solution at different time intervals at 303 K 100

4.9 Variation of corrosion rate with the concentration of Blend extract for mild steel coupons in 1 M HCl solution at different time intervals at 303 K 100

4.10 Comparisons of corrosion rate of the individual extract with the blend at 60 min

at 303 K 101

4.11 Variation of inhibition efficiency with concentration of Afzelia africana extract

for mild steel coupons in 1 M HCl solution at different time intervals at 303 K 101

4.12 Variation of inhibition efficiency with concentration of Brachystegia eurycoma extract for mild steel in 1 M HCl solution at different time intervals at 303 K 102

4.13 Variation of inhibition efficiency with concentration of Momordica charantia

extract for mild steel in 1 M HCl solution at different time intervals at 303 K102

4.14 Variation of inhibition efficiency with extract concentration of the blend for mild steel coupons in 1 M HCl solution at different time intervals at 303 K 103

4.15 Comparisons of inhibition efficiencies of the individual extracts with the blend

at 60 min at 303 K 103

4.16 Variation of corrosion rate with different concentrations of Afzelia africana extract

showing the effect of temperature on the corrosion inhibition process 106

4.17 Variation of corrosion rate with different concentrations of Brachystegia eurycoma

extract showing the effect of temperature on the corrosion inhibition process 106

4.18 Variation of corrosion rate with different concentrations of Momordica charantia

extract showing the effect of temperature on the corrosion inhibition process 107

4.19 Variation of corrosion rate with different concentrations of the blend showing the effect

of temperature on the corrosion inhibition process 107

4.20 Variation of inhibition efficiency with different concentrations of Afzelia africana

extract showing the effect of temperature on the corrosion inhibition process 108

4.21 Variation of inhibition efficiency with different concentrations of Brachystegia

eurycoma extract showing the effect of temperature on the corrosion inhibition process 108

4.22 Variation of inhibition efficiency with different concentrations of Brachystegia eurycoma extract showing the effect of temperature on the corrosion inhibition process 108

4.23 Variation of inhibition efficiency with different concentrations of the blend

showing the effect of temperature on the corrosion inhibition process 109

4.24 Variation of volume of H₂ gas evolved with time for mild steel corrosion in

1.0 M HCl in the absence and presence of the blended seed extract at 303 K 111

4.25 Variation of volume of H₂ gas evolved with time for mild steel corrosion in 1.0 M HCl in the absence and presence of the blended seed extract at 313 K 112

4.26 Variation of volume of H₂ gas evolved with time for mild steel corrosion in 1.0 M HCl

in the absence and presence of the blended seed extract at 323 K 112

4.27 Variation of volume of H₂ gas evolved with time for mild steel corrosion in 1.0 M HCl

in the absence and presence of the blended seed extract at 333 K 113

4.28 Variation of volume of H₂ gas evolved with time for mild steel corrosion in1.0 M HCl

in the absence and presence of the blended seed extract at 343 K 113

4.29 Variation of inhibition efficiency with the concentration of the blended seed extracts

for mild steel corrosion in 1.0 M HCl solution at different temperatures 114

4.30 Variation of temperature with time in 1.0 M HCl for mild steel corrosion in the absence

and presence of the blended seed extracts 116

4.31 Plot of RN against Log of inhibitor concentration 117

4.32 The Langmuir isotherm for the adsorption of Afzelia africana extract on mild steel

surface in 1.0 M HCl 118

4.33 The Freundlich isotherm for the adsorption of Afzelia africana extract on mild steel

surface in 1.0 M HCl 119

4.34 The Temkin isotherm for the adsorption of Afzelia africana extract on mild steel surface in 1.0 M HCl 119

4.35 The Langmuir isotherm for the adsorption of Brachystegia eurycoma extract on mild

steel surface in 1.0 M HCl 120

4.36 The Freundlich isotherm for the adsorption of Brachystegia eurycoma extracts on mild steel surface in 1.0 M HCl 121

4.37 The Temkin isotherm for the adsorption of Brachystegia eurycoma extracts on mild

steel surface in 1.0 M HCl 121

4.38 The Langmuir isotherm for the adsorption of Momordica charantia extract on

mild steel surface in 1.0 M HCl 122

4.39 The Freundlich isotherm for the adsorption of Momordica charantia extract on

mild steel surface in 1.0 M HCl 123

4.40 The Temkin isotherm for the adsorption of Momordica charantia extract on

mild steel surface in 1.0 M HCl 123

4.41 The Langmuir isotherm for the adsorption of the blended seed extracts on mild steel

surface in 1.0 M HCl 124

4.42 The Freundlich isotherm for the adsorption of the blended seed extracts on mild steel

surface in 1.0 M HCl 125

4.43 The Temkin isotherm for the adsorption of the blended seed extracts on mild steel

surface in 1.0 M HCl 125

4.44 Plot of log CR against 1/T for mild steel in 1 M HCl solution in the absence and presence of various concentrations of Afzelia africana extract 130

4.45 Plot of log CR against 1/T for mild steel in 1 M HCl solution in the absence and presence of various concentrations of Brachystegia eurycoma extract 130

4.46 Plot of log CR against 1/T for mild steel in 1 M HCl solution in the absence and presence of various concentrations of Momordica charantia extract 131

4.47 Plot of log CR against 1/T for mild steel in 1 M HCl solution in the absence and presence of various concentrations of blended seed extracts 131

4.48 Plot of log CR/T against 1/T for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of Afzelia africana extract 132

4.49 Plot of log CR/T against 1/T for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of Brachystegia eurycoma extract 132

4.50 Plot of log CR/T against 1/T for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of Momordica charantia extract 133

4.51 Plot of log CR/T against 1/T for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of blended seed extracts 133

4.52 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of Afzelia africana extracts at 303 K 134

4.53 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of Afzelia africana extracts at 313 K 134

4.54 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and

presence of various concentrations of Afzelia africana extracts at 323 K 135

4.55 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Afzelia africana extracts at 333 K 135

4.56 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Afzelia africana extracts at 343 K 135

4.57 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Brachystegia eurycoma extracts at 303 K 136

4.58 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Brachystegia eurycoma extracts at 313 K 136

4.59 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Brachystegia eurycoma extracts at 323 K 136

4.60 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Brachystegia eurycoma extracts at 333 K 137

4.61 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Brachystegia eurycoma extracts at 303 K 137

4.62 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Momordica charantia extracts at 303 K 137

4.63 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Momordica charantia extracts at 313 K 138

4.64 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Momordica charantia extracts at 323 K 138

4.65 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Momordica charantia extracts at 333 K 138

4.66 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of Momordica charantia extracts at 343 K 139

4.67 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of blended seed extracts at 303 K 139

4.68 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of blended seed extracts at 313 K 139

4.69 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of blended seed extracts at 323 K 140

4.70 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of blended seed extracts at 333 K 140

4.71 Plot of Log W_f vs Time for mild steel in 1 M HCl solution in the absence and presence

of various concentrations of blended seed extracts at 343 K 140

4.72 Plot of W_f vs Time for mild steel in 1M HCl solution in the absence and presence of

various concentrations of Afzelia africana extracts at 303K 144

4.73 Plot of 1/W_f vs Time for mild steel in 1M HCl solution in the absence and presence

of various concentrations of Afzelia africana extracts at 303K 144

4.74 Plot of W_f vs Time for mild steel in 1M HCl solution in the absence and presence of

various concentrations of Brachystegia eurycoma extracts at 303K 144

4.75 Plot of W_f vs Time for mild steel in 1M HCl solution in the absence and presence of

various concentrations of Brachystegia eurycoma extracts at 303K 145

4.76 Plot of W_f vs Time for mild steel in 1M HCl solution in the absence andpresence of

various concentrations of Momordica charantia extracts at 303K 145

4.77 Plot of W_f vs Time for mild steel in 1M HCl solution in the absence and presence of

various concentrations of Momordica charantia extracts at 303K 145

4.78 Plot of W_f vs Time for mild steel in 1M HCl solution in the absence and presence of

various concentrations of blended seed extracts at 303K 146

4.79 Plot of 1/W_f vs Time for mild steel in 1M HCl solution in the absence and presence

of various concentrations of blended seed extracts at 303K 146

4.80 SEM micrograph of mild steel immersed in hydrochloric acid without inhibitor at

200μm magnification 149

4.81 SEM micrograph of mild steel immersed in hydrochloric acid in the presence of

ethanol extract of Blend of AA, BE and MC at 200μm magnification 149

4.82 FTIR spectra of the ethanol extract of Blend of AA, BE and MC 152

4.83 FTIR spectra of the corrosion product of mild steel in the presence of the blended extracts in 1 M HCl acid 152

4.84 Optimized Structure of Glucose Leucine, Arginine and Flavonol 156

4.85 HOMO and LUMO orbitals of Leucine 157

4.86 HOMO and LUMO orbitals of Flavonol 157

4.87 HOMO and LUMO orbitals of Glucose 157

4.88 HOMO and LUMO orbitals of Arginine 158

4.89 ESP Optimized mapped density of (a) Leucine, (b) Flavonol and (c) Glucose

(d) Arginine 162

LIST OF PLATES

2.1 Afzelia africana (Akparata) seeds 32

2.2 Brachystegia eurycoma (Achi) seeds 33

2.3 Brachystegia eurycoma (Achi) processed seeds and fruits 33

2.4 Unripe Momordica charantia fruits and leaves 34

2.5 Ripe Momordica charantia fruits and Seeds 35

CHAPTER 1

INTRODUCTION

1.1 BACKGROUND OF STUDY

The importance of mild steel in chemical industry cannot be over-emphasized owing to its usefulness as structural material in several applications including construction of tanks, gas cylinders, pipelines, heat exchangers among others. These serve as basic tools for the industrialization and development of a nation (Senthil et al., 2016; Peter and Sharma 2017; Rathi et al., 2017). Mild steel also known as plain-carbon steel is used in these applications due to its easy availability, low cost and excellent physical properties, but its use and lifespan is restricted in these applications due to its susceptibility towards corrosion (Loto et al., 2012; Singh et al., 2016). One of the most challenging and difficult tasks for industries is the protection of metals from corrosion (Al-otaibi et al., 2012).

The increasing interest in the manufacture of hydrochloric acid has created the need for obtaining information on the corrosion resistance of mild steel to hydrochloric acid attack. Hydrochloric acid is a very important chemical widely used in many industrial activities such as industrial cleaning agent and acid descaling, as well as oil well acid in oil recovery and pickling of mild steel structures (Loto et al., 2012; Chidiebere et al., 2016).

Corrosion as a highly destructive process negatively affects the performance of metallic materials applied in many construction sites. Moreover, their consequences are quite diverse and pose a great problem in the industries, construction and other civil services, costing billions of dollars each year (Onukwube et al., 2016). Mild steel corrodes in different concentrations of aggressive media resulting to a decrease in its original weight. The corrosion of mild steel is attributed to the presence of water, air and ions which accelerate the corrosion process.

In view of the above, efforts are being made to combat this menace by adopting several options including electroplating, oiling, cathodic and anodic protections, and the addition of inhibitors. Inhibitors are often added during industrial processes so as to prevent metal dissolution from inorganic and organic acids which are often employed (Quartarone et al., 2008; Amitha-Rani and Bharathi, 2012). Most effective inhibitors are organic compounds that contain heteroatoms like nitrogen, sulfur, oxygen and phosphorus in a conjugated system (Ebenso et al., 2001; Umoren et al., 2010; Wang, 2012; Xhanari et al., 2017; Lei et al., 2018). The inhibitors function at the interface between the metal and aqueous corrosive media, and their interaction with the metal surface through adsorption, results in a modification in the mechanism of the electrochemical process. Polar functional groups are regarded as the reaction center that promotes the adsorption process (Roberge et al., 1999). Corrosion inhibition helps to reduce the corrosion susceptibility of the metal surface (Umoren et al., 2010, Chidiebere et al.; 2015). As a result, the service life of the metal is prolonged. Most of these inhibitors previously in use are either synthetic chemicals such as chromates and silicates or organic amines with undesired toxic effects on the environment, animal and aquatic life, and are expensive as well. This toxicity may manifest either during the synthesis of the compound or during its application as these inhibitors may cause reversible (temporary) or irreversible (permanent) damage to organ or system viz, kidney, liver etc. hence disturbing the biochemical processes and enzyme systems at some sites in the body (Mohammed-Dabo et al., 2011). The safety and environmental issues of corrosion inhibition arisen in industries have always been a global concern.

Consequently, there exist the need to source for environmentally friendly inhibitors with low toxicity and good efficiency (Anees et al., 2016). In an attempt to find corrosion inhibitors which are environmentally safe and readily available, there has been a growing trend in the use of natural products such as leaves or plant extracts as ecofriendly alternative in protecting metals and alloys in acid cleaning process (Orubite et al., 2004; Awe et al., 2015; Rathi et al., 2017).

The exploration of natural products of plant origin as inexpensive and eco-friendly sources of important inhibitors is an essential field of research owing to the exploitation of abundant phytochemical resources such as alkaloids, tannins, flavonoids, amino acids, lignins, and carbohydrates. These could facilitate the development of environmentally friendly alternatives as against the hazardous synthetic chemical inhibitors. Plant extracts are used extensively in traditional medicine, where the phytochemical constituents have been shown to be effective against pathogenic (disease-causing) micro-organisms and form the basis for several important pharmaceutical drug formulations (Okafor et al., 2005; Oyedeji et al., 2005; Raju and Maridass, 2011). Attempts to extend the field of application of these extracts to solving material corrosion problems in aqueous aggressive environments and hence develop new, inexpensive, efficient, non toxic, readily available, biodegradable and environmentally friendly corrosion-inhibiting additives from cheap and renewable sources are gaining increasing interest (Kumar, 2008; Ekanem et al., 2010; Akalezi et al., 2012; Oguzie et al., 2012). The extracts from the leaves, barks, seeds, fruits and roots comprise of mixtures of organic compounds containing nitrogen, sulfur and oxygen atoms and some have been reported to function as effective inhibitors of metal and alloy corrosion in different aggressive environments. Such studies are justified by the phytochemical constituents of the extracts, which have molecular and electronic structures bearing close similarities with those of conventional corrosion inhibitors and have been shown to also function through adsorption on the metal interface (Awe et al., 2015). Many scientific researchers have responded to this need and it has generated increased research studies into the use of plant extracts (Loto, 2011).

Despite the increasing research studies into the use of plant extracts as inhibitor for metals against corrosion in different aggressive media, it is worthy to note that the use of blends of extracts from Afzelia Africana (Akparata) (AA), Brachystegia eurycoma (Achi) (BE) and Momordica Charantia (MC) seeds as corrosion inhibitor has not been reported in literature. An attempt at making a contribution to this growing research area has necessitated the drive to examine the efficacy of the blends of the above mentioned plant extracts (AA, BE and MC) in corrosion inhibition of mild steel in acidic environment.

1.2 STATEMENT OF THE PROBLEM

Corrosion is an increasingly serious and costly problem that can lead to plant and equipment failures, leakages in oil and gas pipelines as well as steel bridges, ship, and buildings. These failures range from being an annoyance to being catastrophic. It could lead to a direct failure of a component which could affect the entire system. Corrosion cost is not only computed in terms of financial losses, but also in terms of material repairs or replacement, man power and human injuries (Onuchukwu et al., 2004). Organic compounds containing nitrogen, sulfur and oxygen have long been used as potential corrosion inhibitors (Oguzie et al., 2008). These compounds get adsorbed, form a protective layer or insoluble complex on the metal surface and block the active corrosion sites. However, most of these compounds are synthetic chemicals, expensive and very hazardous to both human beings and the environments and need to be replaced with nontoxic and eco-friendly compounds. Over the years, numerous classes of organic compounds have been investigated as corrosion inhibitors. However, the trend in green chemistry is geared towards the replacement of most of these inhibitors with nontoxic, cheap and eco-friendly compounds. In recent years, a number of eco-friendly corrosion inhibitors have been exploited as green alternative to toxic and hazardous compounds (Samuel et al., 2015). Hence, this study seeks to study the efficacy of blends of extracts from Afzelia Africana (AA), Brachystegia eurycoma (BE) and Momordica Charantia (MC) seeds on the corrosion inhibition of mild steel in acidic medium.

1.3 AIM OF THE STUDY

The aim of the study is to investigate the efficacy of blends of extracts from Afzelia Africana (AA), Brachystegia eurycoma (BE) and Momordica Charantia (MC) seeds on the corrosion Inhibition of Mild Steel in acidic medium.

1.4 OBJECTIVES OF THE STUDY

The specific objectives of the study are;

1. To determine the qualitative and quantitative phytochemical analysis of the blends of extracts on the Afzelia africana (AA), Brachystegia eurycoma (BE) and Momordica charantia (MC) seeds.

2. To carry out corrosion test on mild steel using weight loss, hydrogen evolution and thermometric techniques by varying the concentration of the individual seed extract and blending each of the individual seed extracts together at equimolar proportion.

3. To investigate the effect of increase in concentration and temperature on percentage inhibitive efficiency of the individual seed extracts and the blends

4. To ascertain the effect of immersion time on corrosion inhibition of the individual seed extracts and their blends

5. To assess the kinetic and thermodynamic parameters of the inhibitors on the mild steel surface in the aggressive medium.

6. To evaluate the surface characteristics of mild steel in contact with hydrochloric acid solution in the absence and presence of the inhibitor using scanning electron microscope (SEM).

7. To evaluate the relationship between the molecular structures of the plants extract and their inhibition efficiencies using Fourier transform infrared spectroscopic (FTIR) analysis.

8. To evaluate the adsorptive ability of the blended extracts by comparing the infrared spectroscopy (IR) of the extract with the IR of the corrosion product of mild steel in the presence of the blended extracts.

9. To carry out quantum chemical studies on the effective component of the blends of the seed extract.

1.5 SIGNIFICANCE OF THE STUDY

Development of effective and environmentally acceptable corrosion inhibitors as alternatives to toxic and carcinogenic ones are being researched into, forming the interest of the present research to serve as template for steel, oil and gas industries. Most of the corrosion inhibitors are synthetic chemicals, expensive and very hazardous to environment. Therefore, it is desirable to source for environmentally friendly inhibitors. Owing to the increasing ecological awareness as well as the strict environmental regulations, and consequently the need to develop environmentally friendly processes, attention is currently focused on the development of “green” alternatives to mitigating corrosion.

1.6 SCOPE OF THE STUDY

This Study was limited to investigation of inhibitory effectiveness of blends of extracts from Afzelia africana (AA), Brachystegia eurycoma (BE) and Momordica charantia (MC) seeds on mild steel in 1M hydrochloric acid using weight loss, thermometric and hydrogen evolution methods in the absence and presence of each inhibitor at various temperatures. The adsorption and inhibition mechanism of the plant extract was evaluated using quantum chemical calculation and Fourier transform infrared spectroscopic (FTIR) analysis. The surface morphology of the sample was examined using scanning electron micrograph (SEM).

1.7 JUSTIFICATION OF THE STUDY

In view of the aforementioned problem, this work is no doubt justifiable owing to the increasing ecological awareness and the need to develop environmentally friendly processes. Attention is currently focused on the development of “green” alternatives to mitigating corrosion in which the application of blends of extract from Afzelia africana (AA), Brachystegia eurycoma (BE) and Momordica charantia (MC) seeds happen to fall into this category.

Several studies have been carried out on the corrosion inhibition properties of the individual seeds of the above plants, hence, it is most appropriate to utilize the blends of extract from their seeds in the production of corrosion inhibitors to assess their improved or reduced performance in inhibiting corrosion of mild steel in HCl medium. This will also aid in the replacement of some of the organic and inorganic chemical corrosion inhibitors which are known to be hazardous and toxic to human and the environment.

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