Viscosity of Aqueous Solutions of n-butylamine,sec-butylamine and tert-butylamine

Abstract

Viscosities of the systems, water (W) + n-butylamine (NBA), W + sec-butylamine (SBA) and W + tert-butylamine (TBA) have been measured in the temperature range 298.15–323.15K. The viscosities (η) and excess viscosities (η^E) have been plotted against mole fraction of amines (X ₂). On addition of amines to water, viscosities first increase rapidly, then pass through maxima at 0.2 mole fraction of amines and then decline continuously as the addition of amines is continued. η^E show large positive values, with maxima also at 0.2 mole fraction of amines. The maxima of the curves of η and η^E vs. mole fraction of butylamines follow the order, W + TBA > W + SBA > W + NBA. The ascending part of the η vs. X ₂ curves in the water-rich region is explained by the hydrophobic hydration caused by the hydrocarbon tails and the hydrophilic effect due to — NH₂ group of amines. Following the maxima, amine - amine association is preferred, which accounts for the steady decrease of viscosity up to the pure state of amines.     

Dehydrogenation and dehalogenation of amines in MALDI‐TOF MS investigated by isotopic labeling

Secondary and tertiary amines have been reported to form [M–H]⁺ that correspond to dehydrogenation in matrix‐assisted laser desorption ionization time of flight mass spectrometry (MALDI‐TOF MS). In this investigation, we studied the dehydrogenation of amines in MALDI‐TOF MS by isotopic labeling. Aliphatic amines were labeled with deuterium on the methylene of an N‐benzyl group, which resulted in the formation of [M–D]⁺ and [M–H]⁺ ions by dedeuteration and dehydrogenation, respectively. This method revealed the proton that was removed. The spectra of most tertiary amines with an N‐benzyl group showed high‐intensity [M–D]⁺ and [M–H]⁺ ion peaks, whereas those of secondary amines showed low‐intensity ion peaks. Ratios between the peak intensities of [M–D]⁺ and [M–H]⁺ greater than 1 suggested chemoselective dehydrogenation at the N‐benzyl groups. The presence of an electron donor group on the N‐benzyl groups enhanced the selectivity. The dehalogenation of amines with an N‐(4‐halobenzyl) group was also observed alongside dehydrogenation. The amino ions from dehalogenation can undergo second dehydrogenation. These results provide the first direct evidence about the position at which dehydrogenation of an amine occurs and the first example of dehalogenation of haloaromatic compounds in MALDI‐TOF MS. These results should be helpful in the structural identification and elucidation of synthetic and natural molecules. Copyright © 2013 John Wiley & Sons, Ltd.     

Effect of solvent on the free energy of activation of S_N2 reaction between phenacyl bromide and amines

The kinetics of SN2 reaction between phenacyl bromide and various amines in 12 different solvents were studied. Solvent effects on the rate of this reaction and free energy of activation, ΔG# , were interpreted by applying the Abraham-Kam-let-Taft (AKT) equation. UK solvent polarity (π1*), solvent hydrogen-bond basicity (β1) and Hildebrand cohesive density energy (δH2) are those parameters which increase the rate constant and decrease ΔG# , while solvent hydrogen-bond acidity (α1) will have the compensatory effect. A comparison among obtained values of second rate constants, k2, for different amines in a given solvent indicates that the amine reactivities are highly dependent on their structures. The consequent decrease of the rate constant for different amines in any given solvent was found to be: primary > secondary> tertiary. This order results from steric effects of amines.     

Full Characterization of Colloidal Solutions of Long‐Alkyl‐Chain‐Amine‐Stabilized ZnO Nanoparticles by NMR Spectroscopy: Surface State,Equilibria, and Affinity

Full NMR characterization of ZnO nanoparticles (NPs) stabilized by various amines (hexadecylamine, dodecylamine, and octylamine) in C₇D₈ demonstrated that the surface of this apparently simple system was very complex. Using different NMR spectroscopic techniques (¹H, PGSE‐NMR, diffusion‐filtered ¹H NMR, NOESY, ROESY), we observed at least three different modes of interaction of the amines at the surface of the NPs, in thermodynamic equilibrium with the free amines, the relative populations of which varied with their concentration. The first mode corresponded to a strong interaction between a small amount of amine and the ZnO NPs (k_desorp≈13 s^?1). The second mode corresponded to a weak interaction between the amines and the surface of the ZnO NPs (k_off(2)≈50–60 s^?1). The third, and weakest, mode of interaction corresponded to the formation of a second ligand shell by the amine around the NPs that was held together through van der Waals interactions (k_off(1)≈25×10⁵ s^?1). The second and third modes were in fast exchange on the NMR timescales with the free amines. The strongly interacting amines at the NPs surface (first mode) were in slow exchange with the other modes. A complex hydrogen‐bonding network at the NPs surface was also observed, which did not only involve the coordinated amine but also THF and water molecules that remained from the synthesis.     

Cu(I)‐catalyzed Green Synthesis of Propargyl Amines Decorated with Carbazole Moiety by A3 ‐Coupling

A series of novel N ‐alkylcarbazol–propargylamine hybrids were designed and synthesized by Cu^IBr ‐catalyzed A³ ‐coupling of N ‐octylcarbazol‐3‐carbaldehyde, amines, and alkynes. The tri‐substituted propargyl amines decorated with carbazole moiety were obtained under solvent‐free conditions in good to moderate yields. Furthermore, the scope of the method was studied, which was found to be applicable to primary aliphatic and aromatic amines. Also, a large variety of substituents both on alkynes and anilines are well tolerated.     

Structure-Property Relationships in the Basicity and Lipophilicity of Arylalkylamine Oxides

Homologous N,N-dimethyl-phenylalkylamine oxides and N,N-dimethyl-diphenylalkylamine oxides were prepared. Their basicity and lipophilicity (octan-1-ol/H₂O) were compared to those of the parent amines. In contrast to the amines, the basicity of all N,N-dimethyl-arylalkylamine oxides showed very limited pK_a variations (range 4.65 – 5.01) with increasing chain length and number of Ph groups. The N-oxides in their neutral form had a log P^N value lower by 2.77±0.34 (n=9) units than that of the parent amine. The log P^C of the cationic N,N-dimethyl-diphenylalkylamines was lower than that of their neutral form, with a decrement diff(log P^N−C) that increased from 3.25 to 4.21 in the homologous series. Unexpectedly, the decrement diff(log P^N−C) for the N-oxides was much smaller than for the tertiary amines, being 0.23 for the aliphatic N,N-dimethyl-pentylamine oxide, 0.47±0.13 for the phenylalkylamine oxides, and 0.80±0.07 for the diphenylalkylamine oxides. In fact, the protonated N-oxides had log P^C values that were quite comparable to those of the protonated parent amines. Because of the differences in basicity, the difference in distribution coefficients at physiological pH (log D^7.4) between a tertiary arylalkylamine and its N-oxide was 0.82±0.66 (n=9). The pharmacokinetic implication is that N-oxygenation may have a smaller effect on the urinary excretion of tertiary amines than usually assumed.     

Interactions between Amines and Phospholipids: A Chromatographic Study on Immobilized Artificial Membrane (IAM) Stationary Phases at Various pH Values

The chromatographic capacity factors (log k′) for 23 amines were measured by High Performance Liquid Chromatography (HPLC) on a stationary phase composed of phospholipids, the so‐called `Immobilized Artificial Membrane' (IAM). The chromatographic behaviour of the compounds, which consist of primary, secondary, and tertiary amines, and compounds with endocyclic amino functions, was studied with eluents at various pH values (7.0, 5.5, and 3.0). The results were compared both to the octanol/buffer partition values of neutral forms (log P) and to those of mixtures of neutral and ionised forms, existing at the three pH values above mentioned (log D^7.0, log D^5.5, and log D^3.0). At pH 7.0, the log k′ of all secondary and tertiary amines overlapped with those previously observed for neutral isolipophilic compounds. This behaviour was also observed for primary amines, but only for compounds fully ionised at this pH. In contrast, the partially ionised primary amines at pH 7.0 and the compounds with an endocyclic amino function both showed stronger interactions with phospholipids than expected on the basis of log P. The changes in retention observed with eluents at pH 5.5 indicated that retention varies with the ionisation degree of the analytes. At pH 3.0, the interaction between phospholipids and the ionised forms of the amines considered was impaired probably by a change in the charges on the IAM surface. The present study indicates that phospholipids are a partitioning phase that better accommodates the neutral forms of primary amines than does octanol. Moreover, the phospholipid phase is much less sensitive to the ionisation of analytes than octanol, but only at pH 7.0 and 5.5; indeed, the ionised forms of all the amines considered are retained to the same extent as expected for hypothetical neutral isolipophilic compounds. We can thus conclude that, for amines, the partition scale in phospholipids is distinct from the one in octanol.     

The activation of amines of various structures in synergistic mixtures with quinones during the retardation of polymerization of methyl methacrylate

The retardation of the radical polymerization of methyl methacrylate (MMA) mixed with quinones (Q) is accompanied by activation of amines of various structures (InH). In the absence of quinones, primary amines (-naphthylamine), secondary amines (diphenylamine,N-phenyl--naphthylamine, dimethyl-bis-p-(phenylaminophenoxy)silane,N,N'-diphenyl-P-phenylenediamine, andN-phenyl-p-aminophenol), and tertiary amines (N,N,N',N'- tetramethylethylenediamine andN,N,N',N'-tetramethyl-p-phenylenediamine) exert no effect on the process. In the presence of 2,3,5,6-tetrachloroquinone orp-benzoquinone, amines inhibit polymerization (synergism). The consumption of amines is due to the abstraction of mobile H-atoms from their molecules. The retatdation by tertiary amines occurs only in the case when a mobile H atom is present at the-C atom of the amine; a mixture containingN,N,N',N'-tetraphenyl-p-phenylenediamine is ineffective. Analysis of various kinetic schemes shows that the activation of amine and its participation in the reaction with growing MMA radicals may occur either through the formation of active inhibitory species incorporated in the donor-acceptor complex, [InH · Q], or by inhibitory radicals, In^.and QH^., generated by the transfer of an H-atom from InH to Q.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 4, pp. 673–678, April, 1995.     

Effect of amines on the ceric ion-initiated polymerization of vinyl monomers. II. Polymerization of acrylonitrile by ceric ion in presence of various substituted amines

The effect of various substituted amines on the polymerization of acrylonitrile initiated by ceric ammonium sulfate has been studied in aqueous solution at 30°C. It was found that the secondary and tertiary amines considerably increased the rate of polymerization, whereas the primary amines seemed to have no effect at all. From the kinetic studies it was found that the overall polymerization rate R_p is independent of ceric ion concentration and can be expressed by the equation: R_p = k₁ [amine] [monomer] + k₂[monomer]², where k₁ and k₂ are constants (involving different rate constants). The accelerating effect of the amines was attributed to a redox reaction between the ceric ion and the amine involving a single electron transfer, the relative activity of the different amines being thus dependent on the relative electron-donating tendency of the substituents present in the amine. The mechanism of the polymerization is discussed on the basis of these results, and various kinetic constants are evaluated.     

General Catalytic Methylation of Amines with Formic Acid under Mild Reaction Conditions

A general catalytic protocol for the methylation of amines has been developed applying, for the first time, formic acid as the C₁ building block and silanes as reducing agents. A broad range of aromatic and aliphatic, both primary and secondary, amines has been converted to the corresponding tertiary amines including [N‐¹³C]‐labelled drugs in good to excellent yields under mild conditions.     

Facile Synthesis of N‐Carboranyl Amines through an ortho‐Carboryne Intermediate

The efficient o‐carboryne precursor 1‐Li‐2‐OTf‐o‐C₂B₁₀H₁₀ reacts with lithium amides at room temperature to give a series of N‐carboranyl amines in moderate to high isolated yields. This reaction is compatible with a broad substrate scope from primary to secondary, alkyl to aryl amines. The reaction mechanism is also proposed on the basis of experimental results and DFT calculations. This represents the first general and efficient method for the synthesis of 1‐NR¹R²‐o‐carboranes.     

A Laser Flash-Photolysis Study of the Bimolecular Reactions of Singlet Fluorinated Arylnitrenes

The kinetics and mechanisms of the reactions of singlet perfluoro-4-biphenylnitrene and N-propyl-4-nitreno-2,3,5,6-tetrafluorobenzylamide with various amines, pyridine, and dimethylsulfoxide were studied by laser flash photolysis. The reactions of singlet arylnitrenes with amines are two-step processes. The primary step of the process is adduct formation; the rate constant of this reaction is high and lies within the range 4 × 10⁷–2 × 10⁸l mol^–1s^–1for the tested secondary amines. The second step (1,2-hydrogen shift) was accelerated in the presence of water.     

N‐Silylation of Amines Mediated by Et3SiH/KOtBu

Silylation of primary and secondary amines is reported, using triethylsilane as the silylating reagent in the presence of potassium tert‐butoxide (KO^tBu). The reaction proceeds well in the presence of 0.2 equiv. of KO^tBu. In competition experiments, aniline is selectively silylated over aliphatic amines. Computational studies support a catalytic mechanism which is initiated by KO^tBu interacting with the silane to form KH and silylated amine. The KH then takes over the role of base in the propagation of the cyclic mechanism and deprotonates the amine. This reacts with R₃SiH to afford the product R₃SiNR′R′′ and regenerate KH.     

Reactions of 3-cyanochromones with primary amines: structures of the products

Reactions of 3-cyanochromones with primary aromatic amines in boiling benzene gave mixtures of Z- and E-3-arylamino-2-(2-hydroxyaroyl)acrylonitriles and 2-amino-3-(aryl-iminomethyl)chromones. The latter can easily be obtained in the individual state when the reaction is carried out in the presence of triethylamine. In the case of primary aliphatic amines, the open-chain reaction product immediately undergoes cyclization into 3-alkyliminomethyl-2-aminochromones. The structures of the products were examined by 1D and 2D ¹H, ¹³C, and ¹⁵N NMR spectroscopy in DMSO-d₆ and CDCl₃.     

Functional polymers. XIX. Biuret oligomers and polymers of biologically active primary aliphatic amines

Biuret oligomers and polymers from primary aliphatic amines and aromatic or aliphatic diisocyanates have been synthesized. To demonstrate the feasibility of the synthesis of polybiurets, aliphatic primary amines with n-propyl, n-hexyl, n-octyl, and n-dodecyl groups have been incorporated. For the synthesis of biuret oligomers of biologically active primary aliphatic amines [8-(4-amino-1-methylbutylamino)-6-methoxyquinoline] (primaquine) and adamantanamine were selected. Primaquine was also incorporated into polyepichlorohydrin by nucleophilic substitution of the chlorine of the chloromethyl group by the primary aliphatic amino group of primaquine. The structure of the biuret polymers was established by elemental analysis, and by infrared ¹H- and ¹³C-NMR spectroscopic characterization. Several attempts to use primaquine as a diamine for the formation of condensation polymers, including reaction of primaquine with sebacoyl chloride (to form polyamides), or with diisocyanates (to form polyureas) were unsuccessful.     

Synthesis of Derivatives of Pyrazolo[3,4-d]pyrimidines by Reaction of 3,5-Bis(dimethylaminomethylene)amino-4-methoxycarbonylpyrazole and 4-Cyanopyrazole with Amines

The reaction of 3,5-di-(N,N-dimethylaminomethylene)amino-4-methoxycarbonylpyrazole and 3,5-di-(N,N-dimethylaminomethylene)amino-4-cyanopyrazole with different amines occurs with formation of pyrazolo[3,4-d]pyrimidines. In some reactions, an excess of amines leads to their conversion to N,N-dimethylformamidine derivatives. The structure of the compounds obtained has been confirmed by ¹H NMR and ¹³C spectroscopy.     

Quantum semiempirical study on the reactivity of silylated diamines in the synthesis of aromatic polyamides

The reasons for the reactivity increase toward acyl chlorides caused in aromatic amines by silylation are studied by quantum semiempirical and ab initio methods. Silylated amino groups adopt an sp² planar geometry, in contrast to that observed in the unsilylated series, where a partially pyramidal structure intermediate between sp³ and sp² geometry was obtained. Silylation also causes a strong increase of electronic density on the amine nitrogen and an increase of the Highest Occupied Molecular Orbital (HOMO) energy, both effects favoring the higher reactivity of these silylated amines. In addition to that, silylation produces a decrease of the activation energy in the reaction with an acyl chloride, relative to the unsilylated amines, thus increasing reaction rate.     

Pentacoordinated Carboxylate π‐Allyl Nickel Complexes as Key Intermediates for the Ni‐Catalyzed Direct Amination of Allylic Alcohols

Direct amination of allylic alcohols with primary and secondary amines catalyzed by a system made of [Ni(1,5‐cyclooctadiene)₂] and 1,1′‐bis(diphenylphosphino)ferrocene was effectively enhanced by adding nBu₄NOAc and molecular sieves, affording the corresponding allyl amines in high yield with high monoallylation selectivity for primary amines and high regioselectivity for monosubstituted allylic alcohols. Such remarkable additive effects of nBu₄NOAc were elucidated by isolating and characterizing some nickel complexes, manifesting the key role of a charge neutral pentacoordinated η³‐allyl acetate complex in the present system, in contrast to usual cationic tetracoordinated complexes earlier reported in allylic substitution reactions.     

N- and O-arylation with triphenylantimony ortho-phenylenedioxides

2,2,2-Triphenyl-1,3,2-benzodioxastibolanes react with alcohols, phenols, and amines in the presence of copper salts to give the corresponding O- and N-phenyl derivatives. Cyclic Sb^V dialkoxide containing an electron-withdrawing nitro group in the dioxastibolane fragment is most reactive in N-phenylation of primary and secondary amines. Organoantimony analogs containing electron-donating groups are more efficient in O-phenylation of primary and secondary alcohols and phenols.     

Effects of ligands on the “living” radical polymerization initiated by the aged Cr2+ plus benzoyl peroxide system

The “living” radical polymerization of methyl methacrylate with the aged Cr²⁺ plus benzoyl peroxide (BPO) system in the presence of various amines as ligand has been studied in N,N′-dimethylformamide. Aliphatic amines such as ethylenediamine diminished the rate of polymerization, while dipyridyl (dipy) and o-phenanthroline (phen) accelerated the polymerization rate as follows: phen > dipy > pyridine ? none. Specifically, the rate of polymerization in the presence of phen had a maximum value at [phen]/[Cr²⁺] = 0.5. The retardation of polymerization by aliphatic amines was explained by the interaction of BPO with free and coordinated amines. The latter result may support the mechanism involving the complexed radical proposed for the living radical polymerization with the aged Cr²⁺ + BPO system. In the presence of phen the effects of aging period and aging temperature as well as polymerization temperature were studied and the nature of complexed radicals is discussed.