of isatin on MS...Figure 9.6 Optimized, EHOMO and ELUMO frontier molecular orbitals of neutral...Figure 9.7 The most stable energy configuration (a) and the density field (b...9 Chapter 10Figure 10.1 Environmentally sustainable inhibitors for oil–gas industry.Scheme 10.1 Synthesis of chromenopyrazole derivative.Figure 10.2 Structures of some drugs and drug derivatives as corrosion inhib...Figure 10.3 Adsorption and corrosion inhibition of Metformin drug on steel s...Figure 10.4 Structure of some macrocyclic corrosion inhibitors.Scheme 10.2 Synthesis of chitosan Schiff bases for corrosion inhibition of c...Scheme 10.3 Synthesis of bis(2‐aminoethyl)amine‐modified GO (B2AA‐GO).Scheme 10.4 Synthesis of polyethyleneimine‐modified GO (PEI‐GO).
10 Chapter 11Figure 11.1 Adsorption model of chitosan Schiff base over the mild steel sur...
11 Chapter 12Figure 12.1 A description of the different approaches used to mitigate corro...Figure 12.2 Outline of the factors that determine the performance of the cor...Figure 12.3 Some of the commonly investigated green corrosion inhibitors.Figure 12.4 Amino acids with core asymmetrical carbon to which the amino gro...Figure 12.5 Outline of the classification of amino acids.Figure 12.6 Schematic diagram for inorganic–organic core‐shell nanotubes for...
12 Chapter 13Scheme 13.1 The simple description of Passerini reaction.Scheme 13.2 The simple description of Ugi multicomponent reaction.Scheme 13.3 The general pathway of functionalization of mefenamic acid and n...Figure 13.1 Molecular structures of some drugs used as corrosion inhibitors....
13 Chapter 14Figure 14.1 Industries suffering from corrosion.Figure 14.2 Different types of ionic liquids.Figure 14.3 Species that are usually considered as cations and anions for de...Figure 14.4 Number of papers published on the anticorrosive impact of ILs ve...Figure 14.5 Constant adsorption configurations of IPyr‐C2H5 and IPyr‐C4H9 mo...Figure 14.6 Tafel plots of Al utilizing 1M HCl for the process without and w...Figure 14.7 Synthesis route for the [AAE][Sac] ILs.Figure 14.8 Tafel curves for mild steel in 1M HCl solution containing differ...Figure 14.9 Inhibition efficiency of the ILs using AISI 1018 steel in 0.5 an...Figure 14.10 Synthesis of indolium‐based ionic liquids (IBIL‐V) using standa...Figure 14.11 Imidazolium ionic liquids.
14 Chapter 15Figure 15.1 Production scheme of fatty acid and its derivatives.Figure 15.2 Various corrosion inhibitors derived from fatty acids.Scheme 15.1 Synthetic route of palmitic acid imidazole (PI).Figure 15.3 Schematic of the adsorption of the myristic acid imidazoline on ...Scheme 15.2 Synthesis of sulfated fatty acid – diethylamine.Scheme 15.3 Synthesis of imidazole by fatty acid, ethanolamine, and ethanami...Figure 15.4 Schematic of adsorption of oleic acid hydrazide (OAH) on the elb...Scheme 15.4 Hydrolysis reaction of crude Palm oil.Scheme 15.5 Structure of some oleochemical‐based volatile corrosion inhibito...Scheme 15.6 Structure of oleic hydrazide benzoate and oleic hydrazide salicy...Scheme 15.7 Synthesis of hydrazides, thiosemicarbazides, oxadiazoles, triazo...
15 Chapter 16Figure 16.1 General characteristics of inhibitors.Figure 16.2 General properties of carbon nanotubes (CNTs).Figure 16.3 Important applications of carbon nanotubes (CNTs).
16 Chapter 17Figure 17.1 Theoretical parameters of graphene.Figure 17.2 Several common carbon materials.Figure 17.3 The fabricated N‐doped graphene.Figure 17.4 The fabricated N‐doped graphene quantum dots.Figure 17.5 The fabricated processes of graphene oxides.Figure 17.6 The schematic of (a) protecting to the metal structure and (b) f...Figure 17.7 The changes of electrochemical potential of the tested samples i...Figure 17.8 The schematic diagrams of corrosion mechanism for graphene and N...Figure 17.9 The mechanism of anticorrosion performance of (a) without graphe...Figure 17.10 Synthetic route of the graphene and waterborne‐epoxy coatings....Figure 17.11 The self‐repair corrosion‐resistant epoxy film.Figure 17.12 The anticorrosion mechanism of alkyne‐chain‐modified graphene l...Figure 17.13 The possible reactions of the modification of graphene oxide wi...Figure 17.14 Schematic illustration of the preparation of tea polyphenol (TP...Figure 17.15 The dispersion of graphene and corresponding anticorrosion.Figure 17.16 Dispersion of graphene in water using g‐C3N4 as dispersant.Figure 17.17 The polarization curve of nanocomposites coatings after 20 and ...
17 Chapter 18Figure 18.1 Sources of naturally occurring natural polymers.Figure 18.2 Appearance of guar gum.Figure 18.3 Appearance of acacia gum exudate.Figure 18.4 Molecular structure of xanthan gum.Figure 18.5 Basic molecular structure of cellulose.Figure 18.6 Molecular structures of the amylose (a) and amylopectin (b) mole...Figure 18.7 Molecular structure of pectate.Figure 18.8 Molecular structure of chitosan.Figure 18.9 Molecular structure of carrageenan.Figure 18.10 Molecular structure of dextrin.Figure 18.11 Molecular structure of alginate.
18 Chapter 19Figure 19.1 Synthesis of BFP polymer.Figure 19.2 Pictorial representation of mechanism of adsorption of BFP polym...Figure 19.3 Molecular structures of (a) PDPA‐PDMA‐PMEMA and (b) PDEA‐PDMA‐PM...Figure 19.4 The synthesis route of polymer.
19 Chapter 20Figure 20.1 Epoxy cycle found in polyepoxides.Figure 20.2 Formation of α‐chlorohydrins.Figure 20.3 Formation of epoxy rings.Figure 20.4 Structural formula of the DGEBA – relationship between structure...Figure 20.5 Synthesis of bisphenol A diglycidyl ether (DGEBA).Figure 20.6 Degree of hardening as a function of time (s).Figure 20.7 Chemical structure of CAE.Figure 20.8 Chemical structure of BISE.Figure 20.9 Chemical structures of tetra‐functional epoxy resins.Figure 20.10 Chemical structure of epoxy novolac resins.Figure 20.11 Chemical structure of DGEBA resin containing CF3 groups.Figure 20.12 Chemical structures of epoxy resins containing phosphorus.Figure 20.13 Chemical structure of PN‐EP.Figure 20.14 Chemical structures of epoxy resins containing silicon.Figure 20.15 Chemical structures of epoxy resins containing silicon.Figure 20.16 Main chemical reactions taking place during cross‐linking.Figure 20.17 Mechanism of ring opening reaction of epoxy resins in acid solu...Figure 20.18 Chemical structures of epoxy resins containing diols.Figure 20.19 Chemical structures of epoxy resins containing amines.Figure 20.20 Chemical structures of epoxy resins containing phosphorous.Figure 20.21 Chemical structures of epoxy resins containing 2, 4, 6‐trichlor...Figure 20.22 Chemical structures of epoxy resins containing glucose derivati...
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