APPI-MS: Effects of mobile phases and VUV lamps on the detection of PAH compounds

Abstract. The efficiencies of charge exchange reaction in dopant-assisted atmospheric pressure chemical ionization (DA-APCI) and dopant-assisted atmospheric pressure photoionization (DA-APPI) mass spectrometry (MS) were compared by flow injection analysis. Fourteen individual compounds and a commercial mixture of 16 polycyclic aromatic hydrocarbons were chosen as model analytes to cover a wide range of polarities, gas-phase ionization energies, and proton affinities. Chlorobenzene was used as the dopant, and methanol/water (80/20) as the solvent. In both techniques, analytes formed the same ions (radical cations, protonated molecules, and/or fragments). However, in DA-APCI, the relative efficiency of charge exchange versus proton transfer was lower than in DA-APPI. This is suggested to be because in DA-APCI both dopant and solvent clusters can be ionized, and the formed reagent ions can react with the analytes via competing charge exchange and proton transfer reactions. In DA-APPI, on the other hand, the main reagents are dopant-derived radical cations, which favor ionization of analytes via charge exchange. The efficiency of charge exchange in both DA-APPI and DA-APCI was shown to depend heavily on the solvent flow rate, with best efficiency seen at lowest flow rates studied (0.05 and 0.1 mL/min). Both DA-APCI and DA-APPI showed the radical cation of chlorobenzene at 0.05-0.1 mL/min flow rate, but at increasing flow rate, the abundance of chlorobenzene M +. decreased and reagent ion populations deriving from different gas-phase chemistry were recorded. The formation of these reagent ions explains the decreasing ionization efficiency and the differences in charge exchange between the techniques.

Section: Effect Of Solvent Flow Ratementioning

confidence: 99%

Charge Exchange Reaction in Dopant-Assisted Atmospheric Pressure Chemical Ionization and Atmospheric Pressure Photoionization

Vaikkinen

Kauppila

Kostiainen

2016

“…In the absence of experimental thermodynamic data for analyte and solvent clusters and to obtain the ⌬H°and ⌬G°values for the charge exchange (16) and the proton transfer (17,18) reactions when considering solvation, the enthalpy (H) and Gibbs free-energy (G) of S n (n ϭ 1-3), A, (S) n S ϩ· (n ϭ 0 -2), (S) n SH ϩ (n ϭ 0 -2), (S) n A ϩ· (n ϭ 0,1), (S) n AH ϩ (n ϭ 0,1), and S n [SϪH] · (n ϭ 0,1) (where A represents DBT, PY, CAR, or FLU, and S represents CH 3 CN or CH 3 OH) were estimated using density functional theory. Thermodynamic data were calculated for the solvent clustering Reactions (19) to (22) in the gas phase, Table 8:…”

Section: Calculations To Support the Influence Of Solvationmentioning

confidence: 99%

“…Although the mechanisms of ionization associated with these techniques [13][14][15], and with APPI [16,17], are not necessarily the same as that of APCI, certain similarities do exist, and any information obtained regarding APCI may be helpful in understanding these other methods.…”

mentioning

confidence: 99%

Quantitative aspects of and ionization mechanisms in positive-ion atmospheric pressure chemical ionization mass spectrometry

Herrera

Grossert

Ramaley

2008

The behavior in atmospheric pressure chemical ionization of selected model polycyclic aromatic compounds, pyrene, dibenzothiophene, carbazole, and fluorenone, was studied in the solvents acetonitrile, methanol, and toluene. Relative ionization efficiency and sensitivity were highest in toluene and lowest in methanol, a mixture of molecular ions and protonated molecules was observed in most instances, and interferences between analytes were detected at higher concentrations. Such interferences were assumed to be caused by a competition among analyte molecules for a limited number of reagent ions in the plasma. The presence of both molecular ions and protonated analyte molecules can be attributed to charge-transfer from solvent radical cations and proton transfer from protonated solvent molecules, respectively. The order of ionization efficiency could be explained by incorporating the effect of solvation in the ionization reactions. Thermodynamic data, both experimental and calculated theoretically, are presented to support the proposed ionization mechanisms. The analytical implications of the results are that using acetonitrile (compared with methanol) as solvent will provide better sensitivity with fewer interferences (at low concentrations), except for analytes having high gas-phase basicities. (J Am Soc Mass Spectrom 2008, 19, 1926 -1941) © 2008 Published by Elsevier Inc. on behalf of American Society for Mass Spectrometry T he analysis of polycyclic aromatic compounds (PACs) in petroleum and environmental samples has been the subject of many investigations [1-3], due to their impact on the environment, refining processes, and product quality. However, success is often hindered by the number and low concentration of these compounds in such samples, as well as by the lack of standards. Gas chromatography (GC) and GC coupled with electron ionization (EI) mass spectrometry (GC/ MS) are normally employed for samples containing robust, thermally stable analytes [4,5]. Atmospheric pressure ionization methods [6]-electrospray ionization (ESI) [7], atmospheric pressure chemical ionization (APCI) [8], and atmospheric pressure photoionization (APPI) [9]-in conjunction with liquid chromatography (LC) have been used for samples of more problematic analytes.It is generally believed that ESI suffers more from nonlinear response and matrix effects than APCI. Linear response over a wide concentration range is an attractive feature of APCI and has been reported by several authors [10,11]. Recently, Roussis and Fedora compared the ability of APCI and ESI to quantify polar and ionic compounds in petroleum products [12]. They obtained linear ranges of three orders of magnitude for both techniques, and higher sensitivity for ESI. However, the ESI response was nonlinear over the concentration range of interest, and they recommended the use of APCI for quantitative LC/MS applications.In the course of a study of the application of APCI to the analysis of nitrogen-and particularly sulfurcontaining PACs in petroleum samples, we observe...

“…Considering eqs 4 and 5, values of ϳ1 ϫ 10 Ϫ3 , ϳ5 ϫ 10 Ϫ3 , and ϳ4 ϫ 10 Ϫ3 s Ϫ1 can be calculated for k 1 in CH 2 Cl 2 , CHCl 3 , and CCl 4 , respectively. The photoabsorption cross-sections for CH 2 Cl 2 (1.3 ϫ 10 Ϫ16 cm Ϫ2 ) and CHCl 3 (4.2 ϫ 10 Ϫ17 cm Ϫ2 ) were taken from references [24,32]. Based on the model calculations, it can be expected that the resulting APPI(Ϫ)-MS signal intensities increase in the order of CH 2 Cl 2 Ͻ CCl 4 Ͻ CHCl 3 .…”

Section: Mechanistic and Kinetic Considerations Of Chlorinated Adductmentioning

confidence: 99%

“…Very recently, a new ionization method called atmospheric pressure photoionization (APPI) has been developed to broaden the range of analytes that are useful for MS analysis, especially for compounds of low polarity [21,22]. This method has been used to successfully analyze several classes of nonpolar compounds, including polyaromatic hydrocarbons [23][24][25], lipids [26 -28], and steroids [29 -31]. This technique is based on the direct or indirect photoionization of the analyte by vacuum UV (VUV) photons generally emitted from a Kr discharge lamp.…”

mentioning

confidence: 99%

Atmospheric pressure photoionization mass spectrometry of polyisobutylene derivatives

Kéki

Török

Nagy

et al. 2008

Atmospheric pressure photoionization mass spectrometric (APPI-MS) study on three types of polyisobutylene derivatives is reported. Two of the polyisobutylenes investigated were polyisobutylene with dihydroxy and diolefinic end-groups derived from aromatic moieties [dicumyl chloride, 1,4-bis(2-chloro-2-propyl)benzene], and the third contained no aromatic moieties with a monohydroxy end-group. All three polyisobutylene derivatives (PIBs) had an average molecular weight (M n ) of ϳ2000 g/mol, with a polydispersity lower than 1.2. In the positive ion APPI mode, protonated PIB molecules were formed, but the molecular weights obtained were considerably lower than those expected, indicating fragmentation of the PIB chains. In the negative APPI mode, using solvents such as tetrahydrofuran and toluene as dopants, no signal was obtained. However, in chlorinated solvents, such as CCl 4 , CHCl 3 , and CH 2 Cl 2 , in the presence of toluene dopant, PIB adducts with chloride ions were formed with relatively high signal intensity. In the case of CH 2 Cl 2 , no dopant (toluene) was necessary to generate chlorinated adduct ions, albeit increasing the toluene concentration in the flow increased the PIB signal intensity. The effect of the toluene concentration on PIB signal intensity was studied and models that include (1) photoionization of toluene, (2) formation of chloride ions from the chlorinated solvents by dissociative electron capture, (3) formation of chlorinated adduct ions and charge recombination reactions between the toluene radical cation, (4) chloride ions, and (5) olymer characterization, including the determination of molar mass, molar mass distribution, the mass of the repeat unit and end-groups, and functionality, is an important process that can be accomplished using several methods. Mass spectrometric methods, particularly those that utilize soft-ionization techniques, e.g., matrix-assisted laser desorption/ionization (MALDI) [1,2] or electrospray ionization (ESI) [3], are superior to other methods because they offer a unique capability to determine all of these parameters. Contrary to other spectroscopic methods, such as nuclear magnetic resonance (NMR), which can only determine an average value of some of the above parameters [e.g., the number-average molecular weight (M n ) and number average-functionality (F n )], mass spectrometric methods provide not only these average values, but the individual intact polymer molecules can also be detected. However, because soft-ionization is based on forming adduct ions with metal ions, e.g., alkali or silver ions or through protonation and/or deprotonation, mass spectrometric analysis of polymers having moieties that are unable to form ions presents difficulties. This is more pronounced as the polarity of the polymers decreases. For example, mass spectrometric analysis of polar polymers such as polyethylene glycol (PEG) and polypropylene glycol (PPG) can easily be achieved using . Nonpolar polymers such as polystyrenes are also amenable to MALDI and ESI through the f...