Thermal Stability of Various Chelates that are Used in the Oilfield

Sokhanvarian, Khatere

14 March 2013

Acid treatment, especially at high temperatures, is very challenging since HCl is really corrosive to the metal equipment. The use of HCl is associated with face dissolution, corrosion, and iron precipitation. Organic acids are weak and less corrosive than HCl but they have a limitation, which means that they can't be used at high concentrations. The next option would be chelating agents. Chelating agents are used in well stimulation, iron control during acidizing, and removal of inorganic scales. Chelates such as ethylenediaminetetraacetic acid (EDTA), N-(hydroxyethyl)-ethylenediaminetetraacetic acid (HEDTA), L- glutamic acid-N, N diacetic acid (GLDA), and nitrilotriacetic acid (NTA) are used in high-pressure/high-temperature oil and gas wells. GLDA is environmentally friendly, which makes it favorable. One of the concerns with these chelates is their thermal stability at high temperatures because if they degrade at high temperatures, they may lose their functionality. This study describes the thermal stability of these chelates, thermal degradation products, and some methods to improve their stability. The thermal stability is determined by measuring the concentration before and after heating using a complexo-metric titration utilizing FeCl₃ as a titrant. The degradation products are identified using Mass Spectrometry (MS). A series of experiments were run in the lab at varying temperatures (300 to 400°F) up to 12 hours, and the results shows chelates are not stable at temperatures greater than 350°F. Furthermore, chelates with two nitrogen atoms are more stable than those with one nitrogen atom. Iminodiacetic acid (IDA), acetic acid, and [alpha]-hydroxy acids are the decomposition products. There is a layer of black deposition after the chelates are heated, which is analyzed using Scanning Electron Microscope (SEM). Some coreflood tests are conducted using these degraded chelates to investigate the effect of these solid precipitates on the permeability of carbonate and sandstone cores. Increasing ionic strength and raising pH results in a higher thermal stability. Some salts such as, NH₄Cl, KCl, Csformate, and NaBr are added to chelate solutions to enhance stability.

Stimulation

Oilfield

Chelates

Thermal Stability

Influence of bridging groups on the reactivity of dinuclear platinum (II) complexes with bis(2-pyridylmethyl)amine chelate headgroups.

Mambanda, Allen.

January 2009

The influence on the reactivity of both the length as well as the structural nature of diamine bridges linking dinuclear Pt(II) complexes with homotopic bis(2-pyridylmethyl)amine headgroups has been investigated. For this purpose, three sets of square-planar Pt(II) complexes sharing a common non-labile bis(2-pyridylmethyl)amine chelate were synthesized and characterized by various spectroscopic methods. The substitution of the coordinated aqua ligands by three thiourea nucleophiles of different steric demands was studied in acidic aqueous medium under pseudo first-order conditions. The reactions were studied as a function of concentration, temperature and in some cases under an applied pressure using the standard stopped-flow technique and UV-visible spectrophotometry. Their thermodynamic properties were investigated by studying the acid-base equilibria of the coordinated aqua ligands using a spectrophotometric titration method. DFT Quantum mechanical calculations were also performed to determine their geometry-optimized structures and energies of the frontier molecular orbitals. The first set of Pt(II) complexes comprise dinuclears, all bridged by a flexible α,ω-alkyldiamines. The second set of complexes is Pt(II) amphiphilic mononuclear analogues of the former set, formed intuitively by excising off one of the Pt(II) chelate headgroups. The last set of complexes comprises Pt(II dinuclear complexes which are structurally related to the first set, but are linked by relatively rigid linkers, which are made up of either phenyldiamine or diaminocyclohexane fragments. In two of the complexes, a single methylene spacer (CH2 In general, the substitution reactions of the coordinated aqua ligands of all the Pt(II) complexes by the three sulfur donor nucleophiles (Nu) proceed via a two-step reaction pathway. The first step, whose rate constant is denoted in subsequent text as k) group is incorporated between the rigid moieties of the diamine bridge so as to elongate the average distances separating their Pt(II) atoms as well as to modulate the rigidity of the complexes. For comparison purposes, two monomeric analogues bearing the phenyl and cyclohexyl appended groups, respectively, were studied and reported together with these complexes. 2(1st), involves the substitution of the aqua ligands. The second step, induced by the coordination of the strong labilizing thiourea nucleophiles and whose rate constant is denoted in the text as k2(2nd), is ascribed to the dechelation of the one of the cis-coordinated pyridyl units. Thus, the substitution of the aqua ligands and the subsequent dechelation of the pyridyl units, can be expressed as kobs(1st/2nd) = k2(1st/2nd)[Nu] for all the reactions. Negative entropy of activation, negative volume of activation (in cases where measurements were carried out) and second-order kinetics for the substitution reactions all support an associative mode of activation. The substitution reactivity of all the dinuclear complexes is influenced to a greater extent by the steric influences conferred by the bridge as well as a weak electronic effect. The steric influences are mutual, axially exerted and seemingly unique to the square-planar terdentate chelate headgroups. The steric influences depend strictly on length of the diamine (i.e., the average distances separating the Pt centres of the dinuclears) as well as molecular symmetries and shapes of the complexes. The molecular symmetries and hence the shapes of the complexes depend on the parity of the connecting bonds in the diamine (whether even or not). If the connecting bonds of the bridges are even, C2h structures and hence slip-up molecular geometry are preferred. Their overlap geometries cause mutual and axial steric influences on the Pt(II) square-planar chelates which retard substitutional reactivity when the bridge is short. When odd, bowl-shaped complexes of the C2v point group symmetry are preferred in which the axial steric influences are absent at their Pt(II) chelates. In addition their bowl geometry causes an entrapment of the incoming nucleophiles, causing unusually high reactivity when compared to their even-bridged counterpart. For both molecular symmetries (C2h or C2v), the reactivity of the dinuclear complex depends on the average distances separating the Pt(II) centres of the dinuclears. In the former type of complexes, when the average distances separating their Pt(II) centres are long, the axial steric influences at each Pt(II) chelate due to their C2h The chain length as well as the structural make-up of the linker also determines the amount of electron density donated inductively from the linker to the Pt ions as well as the effective nuclear charge at each Pt(II) centre due to charge addition. These are two opposing overlap geometry is weakened, leading to enhanced reactivity as the chain length is increased. In the latter type of complexes, this weakens the ‘entrapment’ effect of their bowl-shaped geometry, resulting in a steady decrease in reactivity when the chain length of the linker is increased. In addition rigidity and planarity within the backbone of the diamine bridge has been found to distort the bowl cavity causing weakening of the ‘entrapment effect’ resulting in the lower rates than expected. iv factors which also influence the rate of substitution in these complexes to some extent. The inductive effect as well as the presence of a domineering steric influence in the C2h overlap geometry was verified by studying the reactivity of the analogous amphiphilic Pt(II) complexes. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2009.

Platinum compounds.

Chelates.

Theses--Chemistry.

Influence of bridging groups on the reactivity of dinuclear platinum (II) complexes with bis(2-pyridylmethyl)amine chelate headgroups.

Mambanda, Allen.

January 2009

The influence on the reactivity of both the length as well as the structural nature of diamine bridges linking dinuclear Pt(II) complexes with homotopic bis(2-pyridylmethyl)amine headgroups has been investigated. For this purpose, three sets of square-planar Pt(II) complexes sharing a common non-labile bis(2-pyridylmethyl)amine chelate were synthesized and characterized by various spectroscopic methods. The substitution of the coordinated aqua ligands by three thiourea nucleophiles of different steric demands was studied in acidic aqueous medium under pseudo first-order conditions. The reactions were studied as a function of concentration, temperature and in some cases under an applied pressure using the standard stopped-flow technique and UV-visible spectrophotometry. Their thermodynamic properties were investigated by studying the acid-base equilibria of the coordinated aqua ligands using a spectrophotometric titration method. DFT Quantum mechanical calculations were also performed to determine their geometry-optimized structures and energies of the frontier molecular orbitals. The first set of Pt(II) complexes comprise dinuclears, all bridged by a flexible α,ω-alkyldiamines. The second set of complexes is Pt(II) amphiphilic mononuclear analogues of the former set, formed intuitively by excising off one of the Pt(II) chelate headgroups. The last set of complexes comprises Pt(II dinuclear complexes which are structurally related to the first set, but are linked by relatively rigid linkers, which are made up of either phenyldiamine or diaminocyclohexane fragments. In two of the complexes, a single methylene spacer (CH2) group is incorporated between the rigid moieties of the diamine bridge so as to elongate the average distances separating their Pt(II) atoms as well as to modulate the rigidity of the complexes. For comparison purposes, two monomeric analogues bearing the phenyl and cyclohexyl appended groups, respectively, were studied and reported together with these complexes. In general, the substitution reactions of the coordinated aqua ligands of all the Pt(II) complexes by the three sulfur donor nucleophiles (Nu) proceed via a two-step reaction pathway. The first step, whose rate constant is denoted in subsequent text as k2(1st), involves the substitution of the aqua ligands. The second step, induced by the coordination of the strong labilizing thiourea nucleophiles and whose rate constant is denoted in the text as k2(2nd), is ascribed to the dechelation of the one of the cis-coordinated pyridyl units. Thus, the substitution of the aqua ligands and the subsequent dechelation of the pyridyl units, can be expressed as kobs(1st/2nd) = k2(1st/2nd)[Nu] for all the reactions. Negative entropy of activation, negative volume of activation (in cases where measurements were carried out) and second-order kinetics for the substitution reactions all support an associative mode of activation. The substitution reactivity of all the dinuclear complexes is influenced to a greater extent by the steric influences conferred by the bridge as well as a weak electronic effect. The steric influences are mutual, axially exerted and seemingly unique to the square-planar terdentate chelate headgroups. The steric influences depend strictly on length of the diamine (i.e., the average distances separating the Pt centres of the dinuclears) as well as molecular symmetries and shapes of the complexes. The molecular symmetries and hence the shapes of the complexes depend on the parity of the connecting bonds in the diamine (whether even or not). If the connecting bonds of the bridges are even, C2h structures and hence slip-up molecular geometry are preferred. Their overlap geometries cause mutual and axial steric influences on the Pt(II) square-planar chelates which retard substitutional reactivity when the bridge is short. When odd, bowl-shaped complexes of the C2v point group symmetry are preferred in which the axial steric influences are absent at their Pt(II) chelates. In addition their bowl geometry causes an entrapment of the incoming nucleophiles, causing unusually high reactivity when compared to their even-bridged counterpart. For both molecular symmetries (C2h or C2v), the reactivity of the dinuclear complex depends on the average distances separating the Pt(II) centres of the dinuclears. In the former type of complexes, when the average distances separating their Pt(II) centres are long, the axial steric influences at each Pt(II) chelate due to their C2h overlap geometry is weakened, leading to enhanced reactivity as the chain length is increased. In the latter type of complexes, this weakens the ‘entrapment’ effect of their bowl-shaped geometry, resulting in a steady decrease in reactivity when the chain length of the linker is increased. In addition rigidity and planarity within the backbone of the diamine bridge has been found to distort the bowl cavity causing weakening of the ‘entrapment effect’ resulting in the lower rates than expected. The chain length as well as the structural make-up of the linker also determines the amount of electron density donated inductively from the linker to the Pt ions as well as the effective nuclear charge at each Pt(II) centre due to charge addition. These are two opposing factors which also influence the rate of substitution in these complexes to some extent. The inductive effect as well as the presence of a domineering steric influence in the C2h overlap geometry was verified by studying the reactivity of the analogous amphiphilic Pt(II) complexes. / Thesis (D.Phil.)-University of KwaZulu-Natal, 2009. / National Research Foundation and University of KwaZulu-Natal

Platinum compounds.

Chelates.

Theses--Chemistry.

The effect of methylation upon the antioxidant and chelation capacity of quercetin and dihydroquercetin in a lard substrate

Crawford, David Lee

29 March 1961

Graduation date: 1961

Quercetin

Chelates

Food additives

Antioxidants

Is zinc a new class of neurotransmitter? a presynaptic model /

Ketterman, Joshua K.

January 2006

Thesis (M.S.)--Ohio University, August, 2006. / Title from PDF t.p. Includes bibliographical references.

Salsola kali (tumbleweed) a possible biomonitoring device for the detection of airborne heavy metals /

Benitez, Tenoch.

January 2009

Thesis (M.S.)--University of Texas at El Paso, 2009. / Title from title screen. Vita. CD-ROM. Includes bibliographical references. Also available online.

Studies toward the development of an electronically switchable ion exchange system

Johnson, Ashley Michelle, Holcombe, James A.,

January 2004

Thesis (Ph. D.)--University of Texas at Austin, 2004. / Supervisor: James A. Holcombe. Vita. Includes bibliographical references. Also available from UMI.

Ion exchange. Metals. Ligands. Chelates.

Role of iron in the accumulation of glomalin, an arbuscular mycorrhizal fungal glycoprotein

Nichols, Kristine Ann.

January 1999

Thesis (M.S.)--West Virginia University, 1999. / Title from document title page. Document formatted into pages; contains viii, 85 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references.

Using organic amendments and chelates for remediation of metal-contaminated soils by vetiveria zizanioides

Chiu, Ki Kin

01 January 2003

No description available.

Chelates

Effect of heavy metals on

Vetiver

A commercial process development for plant food formulation using polyprotic acids from natural extracts as chelating agents

Ndibewu, Peter Papoh

January 2005

The citrus industry is one of South Africa's largest agricultural sectors in terms of export earnings with lemon fruits and juice as a trendsetter due to their high grade quality. According to growers, the Eastern Cape Province of South Africa alone produces an excess of about 10-14,000 tons of lemon juice which is presently of no economic value due to the sour taste and “bitterness”. As a result of this excess and in order to make use of the polyprotic acids naturally occurring in the lemon juice, four fertilizer nutrient mixtures are formulated, using lemon juice as base. From a conceptual scientific approach, characterization (physico-chemical and functional properties determinations) of Eureka Lemon fruit juices were undertaken, followed by smaller scale batch formulation experiments. On the basis that these lemon juice-based fertilizer mixtures are prepared following standard liquid fertilizer formulation guidelines, a field test was conducted to evaluate their potential effectiveness to influence plant growth. A growth chamber testing on tomato plants revealed high growth response (> 99.9 % certainty) potential in two of the semi-organic mixtures formulated while the organic mixture showed a relatively good growth rate as compared to the control (pure tap water). According to statistical analysis (ANOVA) comparison, two of the semi-organic mixtures performed considerably better than the two commercial samples evaluated. Potential benefits profoundly associated with these nutrient mixtures as compared to similar liquid fertilizer products on the market is that most nutrients are chelated and dissolved in solution. Also, the mixtures contain all necessary nutrients including plant growth substances required for healthier plant growth. The most important socioeconomic impact is the value addition to the technology chain in the citrus industry. The use of fluid fertilizers in significant quantities is less than twenty years old. Nevertheless, growth has been so rapid that in South Africa demand for mixed liquid fertilizer has greatly increased from 90 000 tons NPK & blended micronutrients in 1955 to more than 600 000 per annum tons today (Report 41/2003, Department of Minerals and Energy). The liquid fertilizers market is sparsely specialized with major competitors like Omnia, Kynoch and Foskor supplying more than 50 % of the market demand. Amongst the nutrient mixtures formulated, mixture one is an NPK (1-1-2) based nutrient mixture containing both secondary nutrients (0.5 % Mg & 1.0 % Ca) and seven micronutrients (0.1 % Fe, 0.05 % Cu, 0.05 % Zn, 0.05 % Mn, 0.02 % B, 0.0005 % Mo and 0.0005 % Co). The composition of this mixture offers the formula a potential to be used as a general purpose (all stages of plant growth) fertilization mixture in view of its balanced composition (containing all essential plant nutrients). Mixture two contains essentially the micronutrients and in higher concentrations (0.3 % Fe, 0.3 % Cu, 0.1 % Zn, 0.2 % Mn, 0.02 % B, 0.0005 % Mo and 0.0005 % Co) as compared to mixture one except for boron, molybdenum and cobalt. The concentration of the micronutrients contained in this mixture is adequately high which offers a potential for it to be used in supplementing nutrition in plants with critical micronutrient-deficient symptoms. Mixture three is very similar to mixture two (1.0 % Fe, 0.05 % Cu, 0.05 % Zn, 0.05 Mn, 0.05 % B, 0.0005 % Mo and 0.0005 % Co) except that the concentrations of all seven micronutrients are considerably less than those of contained in mixture two. However, the concentration of iron in this mixture is as high as 1.0 %. The mixture has a potential to be used in high iron-deficient situations. Mixture four is an organic formula with relatively low nutrient concentrations (NPK-0.02-0.02-1, 0.27 % Mg, 0.02 % Ca, 0.008 % Fe, 0.26 % Cu, 0.012 % Zn, 0.009 % Mn). Nevertheless, this mixture is appealing for organically grown crops where the use of chemicals is prohibited by standards. These lemon juice-based nutrient mixtures were further characterized and tested for stability and storability over a period of eight weeks. This study revealed no major change in the physical quality (colour, pH and “salt out” effect). The basic formulation methodology is a two-step procedure that involves filtration of the lemon juice to remove membranous materials, mixing at ambient temperature and stabilization of the nutrient mixtures. However, for the organic nutrient formula mix, filtration follows after extraction of nutrients from plant materials using the lemon juice.

Chelates

Lemon juice

Liquid fertilizers