33089-36-0

Basic information

• Product Name: 21-CROWN-7
• Synonyms: 21-CROWN-7;1,4,7,10,13,16,19-heptaoxacyclohenicosane;Ccris 3602;Einecs 251-373-3
• CAS NO: 33089-36-0
• Molecular Formula: C₁₄H₂₈O₇
• Molecular Weight: 308.37
• EINECS: 251-373-3
• Mol File: 33089-36-0.mol

Chemical Properties

• Boiling Point: 448.6°Cat760mmHg
• Flash Point: 184.7°C
• Appearance: /
• Density: 0.995g/cm³
• Vapor Pressure: 8.09E-08mmHg at 25°C
• Refractive Index: 1.404
• CAS DataBase Reference: 21-CROWN-7(CAS DataBase Reference)
• NIST Chemistry Reference: 21-CROWN-7(33089-36-0)
• EPA Substance Registry System: 21-CROWN-7(33089-36-0)

Safety Data

• Hazardous Substances Data: 33089-36-0(Hazardous Substances Data)

Usage

Uses

Used in Analytical Chemistry:
21-CROWN-7 is used as a phase-transfer catalyst in organic reactions, facilitating the transfer of reactants between different phases and enhancing the efficiency of the reactions. Its ability to selectively bind metal cations makes it a crucial component in the synthesis of ion-selective electrodes, which are used for the detection and measurement of specific ions in various samples.
Used in Biotechnology:
In the biotechnology industry, 21-CROWN-7 is used as a key component in the development of ionophores. Ionophores are compounds that can selectively transport ions across cell membranes, playing a vital role in various biological processes. The high selectivity of 21-CROWN-7 for potassium ions makes it an ideal candidate for the design of ionophores that can modulate potassium ion transport in biological systems.
Used in Chemical Synthesis:
21-CROWN-7 is employed as a catalyst in the synthesis of various chemical compounds. Its ability to coordinate with metal cations allows for the formation of stable complexes, which can be used to control the reaction pathways and improve the yield of the desired products.
Used in Environmental Applications:
In environmental science, 21-CROWN-7 can be utilized for the selective extraction and separation of metal ions from contaminated water sources. Its high selectivity for specific ions enables the efficient removal of pollutants, contributing to the purification of water and the protection of ecosystems.
Used in Pharmaceutical Applications:
21-CROWN-7 has potential applications in the pharmaceutical industry as a carrier for drug delivery systems. Its ability to form stable complexes with metal cations can be exploited to improve the solubility, stability, and bioavailability of various drug molecules, enhancing their therapeutic efficacy.

InChI:InChI=1/C14H28O7/c1-2-16-5-6-18-9-10-20-13-14-21-12-11-19-8-7-17-4-3-15-1/h1-14H2

Upstream product

• 17455-13-9 18-crown-6 ether 
• 5617-32-3 heptaethylene glycol 
• 112-60-7 Tetraethylene glycol 
• 19249-03-7 triethylene glycol di-(p-toluenesulfonate) 
• 37860-51-8 tetraethylene glycol di(p-toluenesulfonate) 
• 112-27-6 2,2'-[1,2-ethanediylbis(oxy)]bisethanol 
• 31364-42-8 kryptofix 221 
• 23978-09-8 [2.2.2]cryptande 
• 112-26-5 1,2-bis(2-chloroethoxy)ethane 

Downstream Products

• 17455-13-9 18-crown-6 ether 
• 124804-98-4 4-(1,4,7,10,13,16,19-Heptaoxa-cyclohenicos-2-yl)-2-methyl-quinoline 
• 31364-42-8 kryptofix 221 
• 23978-09-8 [2.2.2]cryptande 

Relevant articles and documents

Effect of Crown Ethers on the Selectivity of Electrophilic Aromatic Nitration

Relative rates, isomer distributions, and partial rate factors have been determined for the nitration reactions of benzene, toluene, m-xylene, anisole, and mesitylene with tetrabutylammonium nitrate and trifluoroacetic anhydride in homogeneous CH2Cl2 solutions.The observed selectivity values have been compared with those obtained when 12-crown-4, 15-crown-5, 18-crown-6, 21-crown-7, or 24-crown-8 was added to the nitrating mixture.Small effects, if any, were observed with the smaller ligands, but marked variations in both substrate and positional selectivity appeared in the presence of 18-crown-6, 21-crown-7, and 24-crown-8.Such effects were found to depend on crown ether concentration and to vanish when KClO4 was added.A reaction scheme is proposed where both uncomplexed and complexed nitronium ion contribute to variable extents to the overall reaction.The selectivity of the crown ether associated electrophile relative to the unassociated one seems to result from the balance of two different effects: an increase in the sensitivity to the electronic effects of the substituents and a larger crowding in the transition state.The largest effects on selectivity were observed with 21-crown-7 which causes ortho-para-directing groups to act as essentially para-directing groups.Data for toluene nitration in the presence of 21-crown-7 fit very well the Brown selectivity relationship; the selectivity factor spanning a remarkably wide range on changing the crown ether concentration.

Crown Cation Complex Effects. 21. Spectral Evidence Bearing on the Interaction between Arenediazonium Cations and 21-Crown-7 in Nonpolar Solutions

15-Crown-5 does not complex arenediazonium tetrafluoroborates, but 21-crown-7 is known to complex them more strongly than does 18-crown-6.Despite this, the infrared and ultraviolet band shifts for complex vs. noncomplexed forms are far smaller for the former than for the latter.It is suggested that instaed of the crown completely and tightly surrounding the diazonio function, the crown collars (nearly encircling) the diazonio group and then uses the remaining donor atom(s) either to solvate the terminal nitrogen atom or interact as a base with the ?-acidic aromatic ring, providing additional stability.Since the mode by which 18-crown-6 and 21-crown-7 solvate the diazonium ion in each case differs, the spectral manifestations of this interaction differ.

Facile and rapid synthesis of some crown ethers under microwave irradiation

A series of crown ethers were synthesized from the reaction of 1,8-dichloro-3,6-dioxaoctane with the appropriate hydroxy compound under microwave irradiation in short times and high yields. Copyright Taylor & Francis Group, LLC.

The macrobicyclic cryptate effect in the gas phase

The alkali cation (Li+, Na+, K+, Rb+, and Cs+) binding properties of cryptands [2.1.1], [2.2.1], and [2.2.2] were investigated under solvent-free, gas-phase conditions using Fourier transform ion cyclotron resonance mass spectrometry. The alkali cations serve as size probes for the cryptand cavities. All three cryptands readily form 1:1 alkali cation complexes. Ligand-metal (2:1) complexes of [2.1.1] with K+, Rb+, and Cs+, and of [2.2.1] with Rb+ and Cs+ were observed, but no 2:1 complexes of [2.2.2] were seen, consistent with formation of 'inclusive' rather than 'exclusive' complexes when the binding cavity of the ligand is large enough to accommodate the metal cation. Kinetics for 2:1 ligand-metal complexation, as well as molecular mechanics calculations and cation transfer equilibrium constant measurements, lead to estimates of the radii of the cation binding cavities of the cryptands under gas-phase conditions: [2.1.1], 1.25 ?; [2.2.1], 1.50 ?; [2.2.2], 1.65 ?. Cation transfer equilibrium studies comparing cryptands with crown ethers having the same number of donor atoms reveal that the cryptands have higher affinities than crowns for cations small enough to enter the cavity of the cryptand, while the crowns have the higher affinity for cations too large to enter the cryptand cavity. The results are interpreted in terms of the macrobicyclic cryptate effect: for cations small enough to fit inside the cryptand, the three-dimensional preorganization of the ligand leads to stronger binding than is possible for a floppier, pseudo-two-dimensional crown ether. The loss of binding by one ether oxygen which occurs as metal size increases for a given cryptand is worth approximately 25 kJ mol-1, and accounts for the higher cation affinities of the crowns for the larger metals. The Li+ affinity of 1,10-diaza-18-crown-6 is ~1 kJ mol-1 higher than that of 18-crown-6, while the latter has lower affinity than the former for all of the larger alkali cations (about 7 kJ mol-1 lower for Na+, and about 15 kJ mol-1 lower for K+, Rb+, and Cs+). The equilibrium measurements also allow the determination of relative free energies of cation binding for a number of crown ethers and cryptands. Molecular mechanics modeling with the AMBER force field is generally consistent with the experiments.

Synthesis and Characterization of Large (30-60-Membered) Aliphatic Crown Ethers

We report a new synthetic approach to large (30-72 membered) crown ethers based on isolation of the small and large cyclic polyethers made by combination of 1 mol or 2 mol each, respectively, of oligo(ethylene glycol)s and oligo(ethylene glycol) ditosylates.The advantages of this approach are the use of readily available glycols as starting materials and the ability to optimize the procedure for selective production of either macrocycle, producing yields superior or comparable to previous methods.At higher reaction temperatures the large crown ether is preferentially formed.This approach has been used to produce the crown ethers on 100-g scales.Purification was achieved by a combination of filtration through silica gel, treatment with a polymeric acid chloride, and recrystallization techniques, avoiding standard column chromatography.The pure crown ethers, 60-crown-20, 48-crown-16, 42-crown-14, 36-crown-12, and 30-crown-10, were characterized by melting points, 1H- and 13C-NMR, elemental analysis, and/or MS, GC-MS, and TGA-MS.Melting points were as much as 26 deg C higher than previously reported for these crown ethers.All the aliphatic crown ethers larger than 18-crown-6 decompose upon heating in air at ca. 200 deg C.

Macrocyclic chemistry in the gas phase: intrinsic cation affinities and complexation rates for alkali metal cation complexes of crown ethers and glymes

Reactions of 12-crown-4, 15-crown-5, 18-crown-6, and 21-crown-7, as well as the acyclic analogs triglyme, tetraglyme, and penta(ethylene glycol), with Li+, Na+, K+, Rb+, and Cs+, are observed and characterized using Fourier transform ion cyclotron resonance mass spectrometry (FTICR/MS) and tandem quadrupole mass spectrometry in the gas phase to obtain information on intrinsic host-guest interactions in the absence of the complicating effects of solvation. Radiatively stabilized attachment of the cations to the ligands is a rapid process, with rates in some cases a factor of 2 or more times the Langevin collision rate. The attachment efficiencies increase linearly with cation charge density, suggesting that attachment involves charge-induced rearrangement of the ligands to adopt favorable binding conformations. Attachment is more efficient, and more strongly dependent on charge density, for the cyclic ligands than for their acyclic counterparts. Metal-ligand undergo reaction with a second ligand to form 1:2 metal-ligand complexes, or "sandwiches". The efficiencies of crown sandwich formation are strongly dependent on the ratio of cation radius to binding cavity radius; when the ratio is than one, the efficiencies are too low to measure, but they become measurable at a ratio of 1:1 and increase by about 4 orders of magnitude as the ratio incrrases to about 1.25:1, At higher ratio values, efficiencies fall off slowly, probably due to decreasing cation density. The relative cation affinities of the various ligands are compared both collision-induced dissociation "kinetic" methods, with the tandem quadrupole, and using "bracketing" cation reactions in the FTICR. The tandem quadrupole results are in some cases dependent on the means of producing the 1;2 metal-ligand complexes, and in some cases they do not agree with the FTICR results. The two methods are compared and reasons for the discrepancies are discussed. We favor the FTICR results, which indicate that proton and alkali cation affinities increase with an increase in the number of oxygen donor atoms in the crowns. Equilibria observed in metal exchange reactions between 18-crown-6 and 21-crown-7 were found to always lie on the side of the cation bound to the larger ligand, but K+ has the smallest equilibrium constant of any of the alkali metals, reflecting the excellent size match between K+ and 18-crown-6.

Effect of an ortho-Substituent on the Decomposition of Crown Ether Complexed Arenediazonium Ions in 1,2-Dichloroethane

The effect of an o-substituent (CH3, C2H5 and COCH3) on the complexation and the kinetics of thermal decomposition of arenediazonium tetrafluoroborates in the presence of crown ethers (15-crown-5, 18-crown-6 and 21-crown-7) and the effect of temperature on the decomposition of the complexed ions were studied by UV spectrophotometry in 1,2-dichloroethane.Solid 1:1 complexes were prepared and analyzed (by IR spectroscopy and by decomposition temperature).In the solid state, none of the arenediazonium ions is stabilized by complexation with crown ethers.In solution they form at most very weak charge-transfer complexes with 15-crown-5 but stronger insertion-type complexes with the larger 18-crown-6 and 21-crown-7 molecules (except for the o-acetyl-substituted ion, which is destabilized with increasing and ).The values of the complexation equilibrium constant K and the stabilization ability of the complexation are largest for 21-crown-7, and are much smaller than the corresponding values for the complexation of p- or m-substituted arenediazonium ions with the same complexing agents: e.i. there are clear ortho-effects due to the steric hindrance for the complexation.The values of the activation parameters ΔH and ΔS for the thermal decomposition of the complexed ions are large and positive (largest for 21-crown-7) and suggest an isokinetic relationship for each ion.The complexation in solution causes a hypsochromic shift in the UV spectrum of the arenediazonium ion which is proportional to the strength of the complexation.

TEMPLATE EFFECTS. 7. LARGE UNSUBSTITUTED CROWN ETHERS FROM POLYETHYLENE GLYCOLS: FORMATION, ANALYSIS, AND PURIFICATION

Through the reaction of polyethylene glycols with tosyl chloride and heterogeneous KOH in dioxane not only coronands from crown-4 to crown-8 can be obtained but also larger homologues.A systematic investigation has shown that: i) crown-9 and crown-10 can be formed from nona- and deca-ethylene glycol, respectively, and isolated in pure form; ii) the whole series of polyethylene glycols from tri- to deca-ethylene glycol yields not only the corresponding crown ethers but also higher cyclooligomers that can be analyzed up to about crown-20 by glc: in particular crown-12 and crown-16 were obtained from tetraethylene glycol and purified by column chromatography on cellulose; iii) the reaction, as applied to commercial mixtures of polyethylene glycols (from PEG 200 to PEG 1000), gives fairly high yields of crown ethers also in the region of large ring sizes.The contribution of the template effect of K(+) ion and the cyclooligomerization reactions for the various ring sizes are discussed.

POTASSIUM FLUORIDE ON ALUMINA AS BASE FOR CROWN ETHER SYNTHESIS

Alumina coated with potassium fluoride was found to be an effective and practical reagent for the synthesis of some simple crown ethers.