Analysis of triacetone triperoxide (TATP) and TATP synthetic intermediates by electrospray ionization mass spectrometry

The explosive triacetone triperoxide (TATP) has been analyzed by electrospray ionization mass spectrometry (ESI-MS) on a linear quadrupole instrument, giving a 62.5 ng limit of detection in full scan positive ion mode. In the ESI interface with no applied fragmentor voltage the m/z 245 [TATP + Na](+) ion was observed along with m/z 215 [TATP + Na - C(2)H(6)](+) and 81 [(CH(3))(2)CO + Na](+). When TATP was ionized by ESI with an applied fragmentor voltage of 75 V, ions at m/z 141 [C(4)H(6)O(4) + Na](+) and 172 [C(5)H(9)O(5) + Na](+) were also observed. When the precipitates formed in the synthesis of TATP were analyzed before the reaction was complete, a new series of ions was observed in which the ions were separated by 74 m/z units, with ions occurring at m/z 205, 279, 353, 427, 501, 575, 649 and 723. The series of evenly spaced ions is accounted for as oligomeric acetone carbonyl oxides terminated as hydroperoxides, [HOOC(CH(3))(2){OOC(CH(3))(2)}(n)OOH + Na](+) (n = 1, 2 ... 8). The ESI-MS spectra for this homologous series of oligoperoxides have previously been observed from the ozonolysis of tetramethylethylene at low temperatures. Precipitates from the incomplete reaction mixture, under an applied fragmentor voltage of 100 V in ESI, produced an additional ion observed at m/z 99 [C(2)H(4)O(3) + Na](+), and a set of ions separated by 74 m/z units occurring at m/z 173, 247, 321, 395, 469 and 543, proposed to correspond to [CH(3)CO{OOC(CH(3))(2)}(n)OOH + Na](+) (n = 1,2 ... 5). Support for the assigned structures was obtained through the analysis of both protiated and perdeuterated TATP samples.     

Influence of oxidation state of sulfur on the dissociation of [Tz-(CH2)n-S(O)m-(CH2)n-Tz + Na+] adducts generated by electrospray ionization (Tz = tetrazole ring; n = 2, 3; m= 0, 1, 2)

Sodium adducts of six organosulfur‐α,ω‐ditetrazole compounds (Tz‐(CH₂)_n‐S(O)_m‐(CH₂)_n‐Tz; where Tz = tetrazole ring; n = 2, 3; m = 0, 1, 2) were generated via electrospray ionization (ESI) and their fragmentation pattern assessed via collision‐induced dissociation (CID). Two main dissociation channels were observed: (a) losses of N₂ and HN₃ from the tetrazole rings; (b) cleavage of the C–S bond. The sulfoxides pass predominantly through the second fragmentation pathway, but for the sulfides and sulfones the tetrazole ring fragmentation occurs. Theoretical calculations at the B3LYP/6‐31 + G(d,p) level indicate that for all the adducts (sulfide, sulfoxide, and sulfone) the dissociation pathway that leads to product ions arising from loss of N₂ was the most exothermic. Based on these results and assumptions, it was postulated that the dissociation of the sulfoxide adducts occurs under kinetic control (N₂‐loss pathway via a much more energetic transition state). For the sulfide and sulfone adducts, on the other hand, the dissociation process takes place via a thermodynamically controlled process. Copyright © 2011 John Wiley & Sons, Ltd.     

Organic peroxide production in the Cl2-ethane-air photoreaction system

HPLC along with FT-IR technique was used to study the formation of organic peroxides in the Cl₂-ethane-air photoreaction system. Ethyl hydroperoxide (CH₃CH₂₁OOH, EHP) and peroxyacetic acid ( CH₃C(O)OOH, PAA) were conformed to be the peroxide product in the reaction system. In addition, methyl hydroperoxide (CH₃OOH, hydroxymethyl hydroperoxide (HOCH₂OOH, HMHP) and two unidentified organic peroxides were detected for the first time. EHP and were the dominant peroxide products. The identification of HMHP showed that Criegee biradical CH₂OO may be formed as an intermediate in the oxidation of ethane. Simulation results showed that photooxidation of ethane may make substantial contribution to source of organic peroxides in the atmosphere.     

Organic peroxide production in the Cl2-ethane-air photoreaction system

HPLC along with FT-IR technique was used to study the formation of organic peroxides in the Cl₂-ethane-air photoreaction system. Ethyl hydroperoxide (CH₃CH₂₁OOH, EHP) and peroxyacetic acid ( CH₃C(O)OOH, PAA) were conformed to be the peroxide product in the reaction system. In addition, methyl hydroperoxide (CH₃OOH, hydroxymethyl hydroperoxide (HOCH₂OOH, HMHP) and two unidentified organic peroxides were detected for the first time. EHP and were the dominant peroxide products. The identification of HMHP showed that Criegee biradical CH₂OO may be formed as an intermediate in the oxidation of ethane. Simulation results showed that photooxidation of ethane may make substantial contribution to source of organic peroxides in the atmosphere.     

Features of the First and Second Order Electrospray Ionization Mass Spectra for Salt-Like Products Derived from Monools and Diols Using Combined Reagents Based on ω-Bromoacyl Chlorides and Nitrogen Bases

Derivatization by composite reagents based on ω-bromoacyl chlorides [ClCO(C₂) _n Br (n = 1–4)] and pyridine was applied to study aliphatic and alicyclic alcohols and diols by ordinary and tandem electrospray ionization (ESI) mass spectrometry. The applied derivatization involves the simultaneous acylation of hydroxyl groups with an acyl chloride moiety and the quaternization of pyridine with a terminal bromoalkyl group. Under the ESI conditions, quaternary salts produce corresponding mono and diammonium cations, which are detected in the first-order mass spectra. Collision-induced dissociation (CID) of primary cations generated from monool derivatives gives rise to ammonium cations of the corresponding acids HOOC(CH₂) _n –N⁺(C₅H₅). The CID of primary dications affords the same cations which are also eliminated from dications to form mono-charged fragments.     

CH3OOH和CH3CH2OOH的表征和活性：光电子能谱的研究

The ionization energies of MHP （CH3OOH） and EHP（CH3CH2OOH） nave been determined by Hel photoelectron spectroscopy （PES） measurement and both Gaussian-2 （G2） calculation and Hartree-Fock （HF） method on the basis of Koopmans theorem at 6.311＋G^＊ basis set level for the first time. The assignment and characterization of PE spectra of MHP and EHP were also supported by the G2 and HF calculations. The first ionization energies of MHP and EHP are 9.87 and 9.65 eV, respectively. Higher solubility of EHP in the atmosphere was attributed to their lower ionization energy values.     

Reaction diastereoselectivity of chiral aminoalcohols/[Co(II)NO3]+ complexes in evaporating ESI nanodroplets: new insights from a joint experimental and computational investigation

The nature of the ionic species, formed by electrospray ionization (ESI) of Co(NO₃)₂/CH₃OH solutions with a pair of aminoalcohols W and Y, has been investigated by mass spectrometric and computational methods. Collision induced dissociation (CID) of ions, formally corresponding to the [WYCoNO₃]⁺ structures, yields fragmentation patterns which reflect not only the expected [WYCoNO₃]⁺ connectivity but also that of other isomeric structures. Formation of these latter species is observed only in the presence of a tertiary aminoalcohol, like N‐methylpseudoephedrine. The CID patterns are found to be strongly dependent on the chemical form (whether the free aminoalcohol or its hydrochloride), the configuration, and the relative concentration of the W and Y aminoalcohols. This variability parallels the results of classical MD (molecular dynamics) simulations of the [WYCoNO₃]⁺ adducts which show a drastic alteration of the mechanical–dynamical features of the adducts by simply changing the charge state of W and/or Y, their absolute configuration, or by removing the solvent. The present experimental and computational study confirms the observation of fast stereoselective reactions in ESI nanodroplets before their evaporation and warns against any automatic correlation between the ESI spectrum of an analyte and its structure in solution. Copyright © 2009 John Wiley & Sons, Ltd.     

Fluorinated peroxides derived from hexafluoroacetone. I. Insertion of (CF3)2CO into hydroperoxides

The new fluorinated peroxides HOC(CF₃)₂OOH, HOC(CF₃₂OOC(CF₃) ₂OH, and (CH₃) ₃COOC(CF₃) ₂OH have been prepared by the insertion of hexafluoroacetone into the OH bonds of hydrogen peroxide and t-butyl hydroperoxide. In addition, the alkali metal salts (HOC(CF₃) ₂OOM (M=Li or Na) and (CH₃) ₃COOC(CF₃) ₂ONa have been prepared by neutralization of the corresponding protonic compound with the appropriate metal hydride.The new compounds are safer (i.e., less flammable and less explosive) than analogous or similar hydrocarbon peroxides, though they are somewhat less thermally stable than the parent hydroperoxides.     

Detection of Radical Adducts with Small Molecular Weights by Matrix-Assisted Laser Desorption/Ionization with Fourier Transform Mass Spectrometry

As an alternative method, matrix-assisted laser desorption/ionization with Fourier transform mass spectrometry （MALDI-FTMS） has been successfully used to detect and identify free radical adducts with small molecular weights of hydroxyl and 2-cyano-2-propyl radicals trapped with 5,5-dimethylpyrroline N-oxide （DMPO）. The detection and identification by MS/MS experiments using sustained offresonance irradiation collision-induced dissociation （SORI-CID） of [（DMPO＋·OH-·H）＋H^＋] （m/z 130.0868） and [DMPO＋2 ·CH（CH3）2CN＋H^＋] （m/z 250.1917） have demonstrated that MALDI-FTMS could be an effective method for detection and identification of free radical adducts. Other radical adducts have been also detected and identified. The approach of MALDI-FTMS is simple, fast, and sensitive which has potential for high-throughput analysis.     

Fluorinated peroxides derived from hexafluoroacetone. II. Insertion of (CF3) 2CO into alkali-metal peroxides and subsequent reaction with active halogen compounds

The novel alkali metal peroxide derivatives (CH₃) ₃COOC(CF₃) ₂ONa, NaOC(CF₃) ₂OOC(CF₃) ₂ONa and CF₃C(O) OOC(CF₃) ₂ONa have been prepared through reactions of hexafluoroacetone, (CF₃) ₂CO, with the sodium salts of various organic hydroperoxides. These new salts are soluble in water and polar organic solvents and have been used to prepare the new covalent fluorocarbon/hydrocarbon peroxides [(CH₃₃COOC(CF₃) ₂OC(O)C₆H₅, (CH₃) ₃SiOC(CF₃) _2-OOC(CF₃) ₂OSi(CH₃) ₃, and (CH₃₃COOC(CF₃) ₂C(O)CF₃] through reaction with compounds having active halogen. Although the new peroxides are apparently less flammable and explosive than their hydrocarbon analogs, they also exhibit shorter half-lives than the parent compound (i.e., the peroxide without hexafluoroacetone insertion).     

Identification and fragmentation pathways of caffeine metabolites in urine samples via liquid chromatography with positive electrospray ionization coupled to a hybrid quadrupole linear ion trap (LTQ) and Fourier transform ion cyclotron resonance mass spectrometry and tandem mass spectrometry

Liquid chromatography (LC) with positive ion electrospray ionization (ESI+) coupled to a hybrid quadrupole linear ion trap (LTQ) and Fourier transform ion cyclotron resonance mass spectrometry (FTICRMS) was employed for the simultaneous determination of caffeine and its metabolites in human urine within a single chromatographic run. LC/ESI‐FTICRMS led to the unambiguous determination of the molecular masses of the studied compounds without interference from other biomolecules. A systematic and comprehensive study of the mass spectral behaviour of caffeine and its fourteen metabolites by tandem mass spectrometry (MS/MS) was performed, through in‐source ion trap collision‐induced dissociation (CID) of the protonated molecules, [M+H]⁺. A retro‐Diels‐Alder (RDA) process along with ring‐contraction reactions were the major fragmentation pathways observed during CID. The base peak of xanthine precursors originates from the loss of methyl isocyanate (CH₃NCO, 57 Da) or isocyanic acid (HNCO, 43 Da), which in turn lose a CO unit. Also uric acid derivatives shared a RDA rearrangement as a common fragmentation process and a successive loss of CO₂ or CO. The uracil derivatives showed a loss of a ketene unit (CH₂CO, 42 Da) from the protonated molecule along with the loss of H₂O or CO. To assess the potential of the present method three established metabolite ratios to measure P450 CYP1A2, N‐acetyltransferase and xanthine oxidase activities were evaluated by a number of identified metabolites from healthy human urine samples after caffeine intake. Copyright © 2009 John Wiley & Sons, Ltd.     

Formation of organic peroxides in the photooxidation of CH4

The formation of organic peroxides in the Cl-atom-initiated photooxidation of CH₄ in O₂-N₂ mixtures at 101 325 Pa and 298 K was studied with HPLC and FT-IR methods. Four peroxidic products were detected, which were H₂O₂, hydroxymethyl hydroperoxide (HOCH₂OOH; HMHP), methyl peroxide (CH300H; MHP) and dimethyl peroxide (CH₃00CH₃). A chromatogram peak at retention time of 8.08 min was assigned tentatively to peroxyformic acid (HC(O)OOH). The identification of HMHP in the reaction system showed that one of the reaction paths for the self-reaction of CH₃00. led to producing Criegee intermediate CH₂OO. The formation mechanism of organic peroxide in the photooxidation of CH₄ is more complicated than it was assumed before. Photooxidation of CH₄ is probably an important source of organic peroxides in the troposphere. Project supported by the State Scientific and Technological Commission of China (Grant No. E96-05)     

Intermetallic Competition in the Fragmentation of Trimetallic Au–Zn–Alkali Complexes

Cationization is a valuable tool to enable mass spectrometric studies on neutral transition‐metal complexes (e.g., homogenous catalysts). However, knowledge of potential impacts on the molecular structure and catalytic reactivity induced by the cationization is indispensable to extract information about the neutral complex. In this study, we cationize a bimetallic complex [AuZnCl₃] with alkali metal ions (M⁺) and investigate the charged adducts [AuZnCl₃M]⁺ by electrospray ionization mass spectrometry (ESI‐MS). Infrared multiple photon dissociation (IR‐MPD) in combination with density functional theory (DFT) calculations reveal a μ³ binding motif of all alkali ions to the three chlorido ligands. The cationization induces a reorientation of the organic backbone. Collision‐induced dissociation (CID) studies reveal switches of fragmentation channels by the alkali ion and by the CID amplitude. The Li⁺ and Na⁺ adducts prefer the sole loss of ZnCl₂, whereas the K⁺, Rb⁺, and Cs⁺ adducts preferably split off MCl₂ZnCl. Calculated energetics along the fragmentation coordinate profiles allow us to interpret the experimental findings to a level of subtle details. The Zn²⁺ cation wins the competition for the nitrogen coordination sites against K⁺, Rb⁺, and Cs⁺ , but it loses against Li⁺ and Na⁺ in a remarkable deviation from a naive hard and soft acids and bases (HSAB) concept. The computations indicate expulsion of MCl₂ZnCl rather than of MCl and ZnCl₂.     

The analysis of combustion products : The polarographic determination of the lower organic peroxides

Some lower alkyl and acyl hydroperoxides and dialkyl peroxides have been prepared and their $\text{built}\text{i}{}_{\mathrm{<mtext>d</mtext>}}\text{c}$ values and halfwave potentials have been determined. The halfwave potentials become successively less negative on passing from hydrogen peroxide up the series, the order beingH₂O₂, CH₃OOH, EtOOH, (CH₃)₃COOH, R-CO(OOH)The limiting diffusion currents have been shown to be proportional to the concentrations of individual peroxides, and to be additive in mixtures. Methods have been developed which permit the detailed analysis of mixtures of peroxides containing, for example, hydrogen peroxide, methyl-, tert.-butyl and acetyl hydroperoxides, and diethyl peroxide. The effect of aldehydes has been investigated.     

Improved protonation, collision-induced decomposition efficiency and structural assessment for 'red tide' brevetoxins employing nanoelectrospray mass spectrometry

Brevetoxins are a group of natural neurotoxins found in blooms of red tide algae. Previous electrospray mass spectrometry (ES-MS) studies show that all brevetoxins have high affinities for sodium ions, and they form abundant sodium adduct ions, [M + Na]+, in ES-MS, even when trace contamination is the only source of sodium ions. Attempts to obtain informative product ions from the collision-induced decomposition (CID) of [M + Na]+ brevetoxin precursor ions resulted only in uninformative sodium ion signals, even under elevated collision energies. In this study, a nano-ES-MS approach was developed wherein ammonium fluoride was used to form cationic [M + NH4]+ adducts of brevetoxin-2 and brevetoxin-3; a significant increase in the abundance of protonated brevetoxin molecules [M + H]+ also resulted, whereas the abundance of sodium adducts of brevetoxins [M + Na]+ was observed to decrease. Under CID, both [M + NH4]+ and [M + H]+ gave similar, abundant product ions and thus underwent the same types of fragmentation. This indicated that ammonium ions initially attached to brevetoxins forming [M + NH4]+ easily lose neutral ammonia in a first step in the gas phase, leaving protonated brevetoxin [M + H]+ to readily undergo further fragmentation under CID.     

Structural analysis of diacyl peroxides by electrospray tandem mass spectrometry with ammonium acetate: bond homolysis of peroxide-ammonium and peroxide-proton adducts

Organic peroxides have significant implications in organic chemistry and biological processes. The weak O-O bond makes them extremely difficult to characterize by conventional analytical methods. Diacyl peroxides are one of the major radical sources in polymerization and organic synthesis. It is well known that diacyl peroxides are thermal labile and thus are not amenable to study by gas chromatography/mass spectrometry (GC/MS). Electrospray tandem mass spectrometry (ESI-MS/MS) has been applied to the structural analysis of diacyl peroxides by formation of ammonium adducts. Collision induced dissociation (CID) studies of the ammonium adducts of the peroxide [M + NH(4)](+) give collision energy dependent fragments. For most diacyl peroxides, homolysis of the peroxy bond predominates the fragmentation pathways of the peroxide-ammonium adducts. Deuterated substrates have been employed to provide evidence for typical fragmentation pathways. The CID studies were also used to locate the O-18 in some O-18 specifically labeled diacyl peroxides. For branched alkyl or alkoxy substrates, McLafferty rearrangement and decarboxylation become a major pathway. By comparison with some anhydride analogues, ESI-MS/MS can also be used to study this class of compounds.     

Mass-analysed ion kinetic energy and collisionally induced dissociation mass spectra of clusters of acetylated xylo-oligosaecharides with protonated ammonia and methylannine

Per-O-acetylated methyl glycosides of D -xylan-type di- and trisaccharides were studied by mass-analysed ion kinetic energy (MIKE) and collisionally induced dissociation (CID) mass Spectrometry using protonated ammonia and methylamine, respectively, as reaction gases in chemical ionization (CI). The oligosaccharides form abundant cluster ions, [M + NH₄]⁺ or [M + CH₃NH₃]⁺, and the main fragmentation of these ions in the MIKE and CID spectra is the cleavage of interglycosidic linkages. Thus, CI (NH₃) or CI (CH₃NH₂) spectra in combination with the MIKE or CID spectra allow the molecular masses, the masses of monosaccharide units and the branching point in oligosaccharides to be established. In the case of disaccharides, it is possible to distinguish the (1 → 2) linkage from the other types of linkages.     

Electron transfer dissociation of dipositive uranyl and plutonyl coordination complexes

Reported here is a comparison of electron transfer dissociation (ETD) and collision‐induced dissociation (CID) of solvent‐coordinated dipositive uranyl and plutonyl ions generated by electrospray ionization. Fundamental differences between the ETD and CID processes are apparent, as are differences between the intrinsic chemistries of uranyl and plutonyl. Reduction of both charge and oxidation state, which is inherent in ETD activation of [An^VIO₂(CH₃COCH₃)₄]²⁺, [An^VIO₂(CH₃CN)₄]², [U^VIO₂(CH₃COCH₃)₅]²⁺ and [U^VIO₂(CH₃CN)₅]²⁺ (An = U or Pu), is accompanied by ligand loss. Resulting low‐coordinate uranyl(V) complexes add O₂, whereas plutonyl(V) complexes do not. In contrast, CID of the same complexes generates predominantly doubly‐charged products through loss of coordinating ligands. Singly‐charged CID products of [U^VIO₂(CH₃COCH₃)_4,5]²⁺, [U^VIO₂(CH₃CN)_4,5]²⁺ and [Pu^VIO₂(CH₃CN)₄]²⁺ retain the hexavalent metal oxidation state with the addition of hydroxide or acetone enolate anion ligands. However, CID of [Pu^VIO₂(CH₃COCH₃)₄]²⁺ generates monopositive plutonyl(V) complexes, reflecting relatively more facile reduction of Pu^VI to Pu^V. Copyright © 2011 John Wiley & Sons, Ltd.     

Photooxygenation and gas‐phase reactivity of multiply threaded pseudorotaxanes

The solution‐phase photooxygenation of multiply threaded crown/ammonium pseudorotaxanes containing anthracene spacers is monitored by electrospray ionization Fourier‐transform ion‐cyclotron‐resonance (ESI‐FTICR) mass spectrometry. The oxygenated pseudorotaxanes are mass‐selected and fragmented by infrared multiphoton dissociation (IRMPD) and/or collision‐induced dissociation (CID) experiments and and their behavior compared to that of the non‐oxygenated precursors. [4+2]Cycloreversion reactions lead to the loss of O₂, when no other reaction channel with competitive energy demand is available. Thus, the release of molecular oxygen can serve as a reference reaction for the energy demand of other fragmentation reactions such as the dissociation of the crown/ammonium binding motifs. The photooxygenation induces curvature into the initially planar anthracene and thus significantly changes the geometry of the divalent, anthracene‐spacered wheel. This is reflected in ion‐mobility data. Coulomb repulsion in multiply charged pseudorotaxanes assists the oxygen loss as the re‐planarization of the anthracene increases the distance between the two charges. Copyright © 2016 John Wiley & Sons, Ltd.     

The Atmospheric Oxidation Mechanism of Benzyl Alcohol Initiated by OH Radicals: The Addition Channels

Benzyl alcohol (BA) is present in indoor atmospheres, where it reacts with OH radicals and undergoes further oxidation. A theoretical study is carried out to elucidate the reaction mechanism and to identify the main products of the oxidation of BA that is initiated by OH radicals. The reaction is found to proceed by H‐abstraction from the CH₂ group (25 %) and addition to the ipso (60 %) and ortho (15 %) positions of the aromatic ring. The BA–OH adducts react further with O₂ via the bicyclic radical intermediates—the same way as for benzene—forming mainly 3‐hydroxy‐2‐oxopropanal and butenedial. If NO_x is low, the bicyclic peroxy radicals undergo intramolecular H‐migration, forming products containing OH, OOH, and CH₂OH/CHO functional groups, and contribute to secondary organic aerosol (SOA) formation.