Thermal stability of phosphorylated cellulose modified with various transition metals

Complexes of cellulose phosphate with transition metals such as chromium, manganese, iron, cobalt, nickel, copper, zinc, zirconium, molybdenum, silver, cadmium and mercury have been characterized by reflectance UV-visible spectra. The thermal behaviour of cellulose and the metal complexes of cellulose phosphate in air has been studied by differential thermal analysis and thermogravimetry from ambient temperature to 750°C. From the resulting data, various thermodynamic parameters for different stages of thermal degradation can be obtained following the method of Broido. The activation energies for decomposition of cellulose and metal complexes of cellulose phosphatewere found to kJ mol⁻¹.Pyrolysis-mass spectrometric studies of metal complexes of cellulose phosphate using soft ionization modes such as field ionization and field desorption give very low abundances of volatile products in the spectra compared with the yields with untreated cellulose. The IR and reflectance UV-visible spectra of the pyrolysis residues of metal complexes of cellulose phosphate indicate that dehydration takes place and the metal complexes are stable up to 250°C. At higher temperatures, a compound containing carbonyl groups is formed. A mechanism for the thermal degradation of metal complexes of cellulose phosphate is proposed which explains the generation of reduced amounts of smoke.Scanning electron microscopic studies of cellulose phosphate and its transition metal complexes showed that the fibrillar sites have mostly reacted and throw light on the morphological changes of treated cellulose in the thermal degradation range. The observed effects are of interest with respect to the flame-proofing of cellulose.     

纤维素快速热裂解机理试验研究 Ⅱ. 机理分析

针对在热辐射反应器上得到的纤维素热裂解实验结果，对左旋葡聚糖、1-羟基-2-丙酮以及乙醇醛等一次产物的生成机理进行了分析研究。在气相产物快速析出并急冷的条件下，乙醇醛和1-羟基-2-丙酮二种产物的生成与LG的生成呈现出竞争反应。基于这一结果，我们建立了竞争反应动力学模型，并分别对乙醇醛和1-羟基-2-丙酮进行了模拟，得出二种产物的生成具有相似的动力学行为，表明这两种竞争化合物具有相同的初始反应。分析认为，纤维素的热裂解通过活性纤维素这一反应前体以异裂和均裂两种热解途径进行分解，其中转糖基作用下糖苷键的异裂断开形成了包括LG以及其同分异构体的脱水糖；缩醛结构的开环以及环内C—C键的断裂形成乙醇醛、1-羟基-2-丙酮以及CO等其它小分子化合物。在Brodio-shafizadeh模型的基础上提出了反应机理模型，并按照该模型对高辐射源温度下纤维素热裂解LG的生成进行了模拟，计算结果与实验数据吻合较好。     

Pyrolysis and soft ionization mass spectrometry of aquatic/terrestrial humic substances and soils

The rapid, reproducible, chemical characterization of complex environmental materials such as plants, humic substances and whole soil can be performed by controlled thermal degradation. Except for drying and milling no pre-treatment of the samples is required. Biomacromolecular cleavage during a short degradation step directly in the ion source of a mass spectrometer results in the production of high-mass chemical subunits. Short reaction times and small amounts of sample favour the generation of large, thermal fragments, i.e., chemical building blocks, which can be identified and correlated with the structure of the polymeric biomaterials investigated. The principal aim is to monitor the primary, thermal fragmentation by high molecular ion intensities of the pyrolyzates and to avoid consecutive, mass spectrometric fragmentation as far as possible.For the detection and identification of the pyrolysis (Py) products, a combination with time-/temperature-controlled mass spectrometry (MS) is used. Typical heating rates are 0.2–10°C/s and the temperature range is 50–800°C. Soft ionization techniques such as field ionization (FI), field desorption, chemical ionization (CI) and, to some extent, fast atom bombardment are employed in the positive and negative modes. The results of direct Py-MS are supported by high-resolution mass measurements using electric or photographic detection and Curie-point pyrolysis in combination with gas chromatography-electron ionization/FI/CIMS and library searches for the identification of the pyrolysis products.Fingerprinting and time-resolved Py-MS of aquatic and terrestrial humic substances are reported. The methodology for the investigations of dynamic processes during the volatilization and thermal decomposition of these complex biomaterials is illustrated. Weight loss curves and the temperature function of accurate molecular weight averages for aquatic fulvic and humic acid are derived from the Py-FIMS data. Initial results on the differentiation of soil horizons in a moder profile by Py-FIMS and pattern recognition are presented. In particular, the chemometric evaluation appears promising for future Py-MS studies of humic substances and whole soils, but also for fossil fuels, synthetic polymers and food. In an integrated approach, the linking of conventional chemical and spectroscopic data with the high-mass signals in pyrolysis-mass spectra will be the focus of forthcoming work. Preliminary results for combining wet-chemical data with those of ¹³C nuclear magnetic resonance, Fourier transform infrared and electron spin resonance spectroscopy are put forward in this survey. Finally, initial results of pilot studies to detect biocides such as atrazine directly in soils using Py-FIMS are demonstrated.     

Thermochemical conversion of cellulose in polar solvent (sulfolane) into levoglucosan and other low molecular-weight substances

Pyrolysis of cellulose in sulfolane, an aprotic polar solvent, was conducted at the temperature between 200 and 330 °C. Sulfolane was used as a good solvent for levoglucosan, the major anhydromonosaccharide formed from cellulose pyrolysis, for prevention of the polymerization reaction. Cellulose was observed completely decomposed into soluble products in sulfolane within 3, 10, 60 and 480 min at 330, 280, 240 and 200 °C, respectively. The soluble products had molecular weights less than 500 after acetylation (GPC analysis) and similar product composition to that from cellulose pyrolysis under nitrogen (levoglucosan, levoglucosenone, furfural and 5-hydroxymethylfurfural by HPLC analysis). Pyrolysis of cellulose in polar solvent, which can solubilize anhydromonosaccharides, is proposed as a method for selective formation of levoglucosan and other low molecular-weight (MW) substances. As well, the cellulose pyrolysis in sulfolane did not suffer from carbonization reactions (microscopic and IR spectroscopic analysis) as did cellulose pyrolysis under nitrogen or in dioctyl phthalate (a poor solvent for levoglucosan) which gave brown/black solids. The residues obtained from the pyrolysis in sulfolane were colorless and gave similar IR spectra to that of the original cellulose. Based on these results, a ‘surface-peeling mechanism’ is proposed, and the role of the solvent in the mechanism is discussed.     

生物质主要组分低温热解研究

利用热重分析仪和裂解气质联用仪进行生物质主要组分低温热解特性研究。热重实验结果表明,生物质主要组分的热稳定性为：纤维素>木质素>半纤维素。半纤维素主要热解温度在210℃～320℃,而纤维素和木质素的主要热解温度分别在310℃～390℃和200℃～550℃。裂解气质联用实验考察不同温度对生物质主要组分低温热解产物的影响。半纤维素热解产物主要有乙酸、1-羟基-丙酮和1-羟基-2-丁酮,纤维素热解产物主要包括左旋葡聚糖和脱水纤维二糖,而木质素热解产物主要是邻甲氧基苯酚。     

Characterization of Polymers by Direct Pyrolysis/Chemical Ionization Mass Spectrometry

The characterization of polymers by pyrolysis directly in the ion source of a double focusing magnetic sector mass spectrometer, operating in the chemical ionization mode, is described. Pyrolysis is achieved by two different probe techniques. A low temperature, slow heating rate direct insertion probe (DIP) is used at 400°C, and a specifically constructed high temperature, fast heating rate, high temperature pyrolysis (HTP) probe is used at 1000°C. This probe is capable of achieving pyrolysis temperatures of 1200°C at controlled heating rates up to 20,000°C/s. The mass spectrometric analysis of the pyrolysis products was achieved under chemical ionization (CI) conditions utilizing methane, isobutane, and ammonia as reagent gases. Under CI conditions the molecular ions formed in the mass spectrometer show little tendency to fragment. The CI mass pyrograms are very simple, with each peak in the spectra ascribable to a particular component in the pyrolysis product mixture. The results of the two probe pyrolysis techniques are compared and the utility of each technique for the characterization of polymers is demonstrated using the vinyl polymers polymethyl methacrylate, polyvinyl chloride, and polystyrene.     

Mass spectrometric characterization of substituted 2-thiazolin-4-one derivatives

Electron ionization mass spectrometry was used for the structural characterization of substituted 2-thiazolin-4-one derivatives in the gas phase. The compounds follow common fragmentation pathways, producing ions whose abundances are dependent on the chemical nature of the substituent at position 2. Collision-induced dissociation tandem mass spectrometric experiments, carried out on both molecular ions and fragment ions produced in the source, allowed the elucidation of gas-phase decompositions. The presence of tautomeric forms is suggested for some ionic species. Rapid identification of a primary or secondary amine moiety at position 2 of the thiazoline ring can be achieved by the detection of characteristic fragmentations occurring both in the ion source and under the collision-induced dissociation regime.     

Thermal degradation of spruce needles studied by time-resolved mass spectrometry and multivariate data analysis

In a study related to the impact of air pollution on forests, needles from a healthy and a severely damaged Norway spruce tree were analysed by temperature-programmed pyrolysis/field ionization (FI) mass spectrometry. Dried and pulverized spruce needles were heated at a rate of 0.6°C s^?1 to 450°C in the high vacuum of a FI ion source. Over 100 mass spectra were recorded electrically during each analysis. From each mass spectrum, average molecular weights of the pyrolysis products were calculated; their variation with pyrolysis temperature is discussed. The mass spectra in the range m/z 100–600 are used to calculate partial weight-loss curves. The FI mass spectra are evaluated by principal component analysis and factor rotation. The three-factor spectra based on loadings of the rotated principal components show typical FI signals which are produced during pyrolysis at low, medium and high temperatures. These signal patterns are interpreted as molecular ions of thermally stable, relatively volatile plant constituents and molecular ions of thermal degradation products derived from the thermolysis of carbohydrates, lignin and other biopolymers which occur in conifer needles. Medium- and high-temperature products of lignin can be distinguished. Principal component scores can be used to simulate the appearance of single FI signals, i.e., pyrolysis products. The evaluation of time-resolved pyrolysis and soft ionization mass spectrometric data from a single sample by principal component analysis and factor rotation appears to be suitable for characterization of the major chemical components and their thermal behaviour in complex biological samples.     

Ultraviolet laser desorption/ionization mass spectrometry of single‐core and multi‐core polyaromatic hydrocarbons under variable conditions of collisional cooling: insights into the generation of molecular ions,fragments and oligomers

The ultraviolet laser desorption/ionization of polyaromatic hydrocarbons (PAHs) has been investigated under different background pressures of an inert gas (up to 1.2 mbar of N₂) in the ion source of a hybrid, orthogonal‐extracting time‐of‐flight mass spectrometer (oTOF‐MS). The study includes an ensemble of six model PAHs with isolated single polyaromatic cores and four ones with multiple cross‐linked aromatic and polyaromatic cores. In combination with a weak ion extraction field, the variation of the buffer gas pressure allowed to control the degree of collisional cooling of the desorbed PAHs and, thus, to modulate their decomposition into fragments. The dominant fragmentation channels observed are related to dehydrogenation of the PAHs, in most cases through the cleavage of even numbers of C―H bonds. Breakage of C―C bonds leading to the fragmentation of rings, side chains and core linkages is also observed, in particular, at low buffer gas pressures. The precise patterns of the combined fragmentation processes vary significantly between the PAHs. The highest abundances of molecular PAH ions and cleanest mass spectra were consistently obtained at the highest buffer gas pressure of 1.2 mbar. The effective quenching of the fragmentation pathways at this elevated pressure improves the sensitivity and data interpretation for analytical applications, although the fragmentation of side chains and of bonds between (poly)aromatic cores is not completely suppressed in all cases. Moreover, these results suggest that the detected fragments are generated through thermal equilibrium processes rather than as a result of rapid photolysis. This assumption is further corroborated by a laser desorption/ionization post‐source decay analysis using an axial time‐of‐flight MS. In line with these findings, covalent oligomers of the PAHs, which are presumably formed by association of two or more dehydrogenated fragments, are detected with higher abundances at the lower buffer gas pressures. Copyright © 2014 John Wiley & Sons, Ltd.     

Sensitivity enhancement in tandem liquid chromatographic mass spectrometric assays by summation of two transition ion pairs – perspectives

The introduction of tandem liquid chromatographic mass spectrometric assays has boosted the sensitivity of the bioanalytical determination for the scores of analytes as compared to other conventional modes of detection [1–6]. Additionally, many intelligent variants such as improved ionization potential, suitable adduct formation, and/or identification of a precursor ion, switching of modality of detection (+ve to –ve and vice versa), and derivatization steps (to aid fragmentation and/or impart ionization property) within tandem mass spectrometric assays have further aided in improving the sensitivity. Some researchers have also expressed thoughts of using matrix effects in a beneficial manner so that there may be ion enhancement for improving the sensitivity of the assay.     

质谱参数改变对化合物负离子化学电离质谱行为的影响

负离子化学电离质谱中负离子的相对丰度随着离子源压力、电子能量和离子源温度等质谱参数的改变发生了明显的变化。负离子形成过程中共振电子俘获和裂解电子俘获之间的竞争与质谱参数有关,其中以离子源温度的影响最为显著。热电子的比例随着离子源压力增大而减小,随着电子能量增大而增大。低离子源温度有利于共振俘获形成分子负离子,而高离子源温度则有利于裂解电子俘获形成碎片负离子,特别是热力学稳定的负离子。     

The influence of fine structure on the pyrolysis of cellulose. II. Pyrolysis in air

The pyrolysis of purified celluloses in air at 251°C was studied. The pyrolysis was found to obey first-order kinetics, and the rate constants correlated with the crystallinities, orientations and accessibilities of the samples. The results are interpreted in terms of an oxygen-catalyzed decomposition, with the accessibility of oxygen to the cellulose determining the rate of pyrolysis. The production of levoglucosan under conditions approaching combustion was shown to be a function of the crystallinity and orientation of cellulose. Some levoglucosan appears to be produced from the less ordered regions.     

左旋葡聚糖的制备与在生物技术领域的应用

左旋葡聚糖(LGA)作为一种极具潜力的新糖源,既可以加酸水解为葡萄糖后间接用于微生物发酵,也可以被真菌或细菌甚至构造的基因工程菌直接代谢,目前已经在发酵上展现出良好的应用前景。此外,LGA还可作为碳源,生产生物乙醇、丁二酸等。目前制备LGA普遍采用生物质热解法,该方法存在能耗高、产率低、产物难以提取等缺点,应努力发展在溶剂体系中分解纤维素制备LGA的方法以提高产率。今后的研究应致力于开发微生物代谢LGA的新过程、新方法、新菌种,为LGA的高效利用提供坚实基础。     

Comparison of mass spectrometric methods for studying thermally labile compounds: Rifapentine

Results of 16 different mass spectrometric ionization and sample-introduction methods are compared for the case of a thermally very labile antibiotic, rifapentine. These suggest that extensive thermal decomposition occurs during evaporation when the sample can come into contact with hot metal parts, usually the source housing. The intensity of the molecular ion and the extent of fragmentation depend on various parameters, such as the ionization process, positive or negative-ion detection and the type of sample introduction. The most informative methods for rifapentine seem to be ‘in-beam’ electron impact, negative ionization with particle beam and direct liquid introduction interfaces and positive- and negative-ion fast atom bombardment.     

Curie-point pyrolysis field ionization mass spectrometry of carbohydrates: Part A: Methodology

Methodological aspects of Curie-point pyrolysis in combination with field ionization mass spectrometry for the characterization and identification of carbohydrates are reported. Some monomeric sugars and sugar derivatives have been investigated as a first step towards a basic understanding of the pyrolysis pathways of polysaccharides.Curie-point pyrolysis is performed inside the ion source of a double-focusing mass spectrometer close to the field ion emitter. The pyrolysis products are ionized in a high electric field and spectra of high mass resolution are recorded photographically. This procedure essentially avoids mass spectrometric fragmentation and yields almost exclusively molecular ions of the pyrolysates. The best experimental conditions for pyrolysis were determined by investigating the influences of pyrolysis temperature, temperature pulse length, exposure time and trace impurities on the pyrolysis products. At a temperature of 500°C and a pulse length of 4–6 s, the most significant pyrolysis fragments appear with high relative intensity. Although most of the pyrolysis products with higher volatility are pumped out of the ion source after an exposure time of 3 min, the more characteristic degradation products of lower volatility can still be registered after 10 min. The spectra of monosaccharides such as glucuronic acid, d-glucose and some of its methylated derivatives show significant differences which can be correlated structurally with the position of the substituent.     

Pyrolysis mass spectrometry of terephthalate polyesters using negative ionization

The usual method of studying thermal degradation mechanisms of polymers in vacuo is to use electron ionization pyrolysis mass spectrometry. This can lead to mass spectral fragmentation from the 70 eV electrons used. Low energy electrons (10–15 eV) produce a low abundance of positive ions. However, if a molecule is prone to capture a thermal energy electron, then negative ions are produced in high abundance. This report describes the negative ion pyrolysis mass spectrometry of polyethylene terephthalate and polybutylene terephthalate.     

Comparison of EI and metastable atom bombardment ionization for the identification of polyurethane thermal degradation products

Polyurethanes are widely used in the manufacture of commercial products such as foams and paints. During combustion, these polymers can generate isocyanates, which induce adverse health effects. Polymer pyrolysis (Py) hyphenated with mass spectrometry (MS) allows the investigation of polymer thermal degradation over time/temperature. A diphenylmethanediisocyanate (MDI) polyurethane foam was analyzed with electron ionization (EI) and metastable atom bombardment (MAB) ionization at a pyrolysis temperature of 400 °C. The recently introduced MAB ionization source uses discrete energy stored in metastable atoms of gases to ionize the analytes. This characteristic allows modulation of the ionization energy by simply changing the ionization gas. The extensive fragmentation of molecular ions observed using EI 70 eV is not totally eliminated with EI 10 eV. However, only molecular ions are observed with MAB using N₂ as the ionization gas. Temperature gradients were used to separate the products generated during the thermal degradation of a 1,6-hexamethylenediisocyanate (HDI) polyurethane paint. The analysis of mass spectra was facilitated owing to a selective desorption of pyrolysis products. Furthermore, changing the MAB ionization gas allows elucidation of the structure of the pyrolysis products by controlling the extent of their fragmentation. During these experiments, isocyanic acid, methyleneisocyanate, ethyleneisocyanate, propylisocyanate and butylisocyanate were detected.     

Influence of the interaction of components on the pyrolysis behavior of biomass

There has been much interest in the utilization of biomass-derived fuels as substitutes for fossil fuels in meeting renewable energy requirements to reduce CO₂ emissions. In this study, the pyrolysis characteristics of biomass have been investigated using both a thermogravimetric analyzer coupled with a Fourier-transform infrared spectrometer (TG-FTIR) and an experimental pyrolyzer. Experiments have been conducted with the three major components of biomass, i.e. hemicellulose, cellulose, and lignin, and with four mixed biomass samples comprising different proportions of these. Product distributions in terms of char, bio-oil, and permanent gas are given, and the compositions of the bio-oil and gaseous products have been analysed by gas chromatography-mass spectrometry (GC-MS) and gas chromatography (GC). The TG results show that the thermal decomposition of levoglucosan is extended over a wider temperature range according to the interaction of hemicellulose or lignin upon the pyrolysis of cellulose; the formation of 2-furfural and acetic acid is enhanced by the presence of cellulose and lignin in the range 350-500 °C; and the amount of phenol, 2,6-dimethoxy is enhanced by the integrated influence of cellulose and hemicellulose. The components do not act independently during pyrolysis; the experimental results have shown that the interaction of cellulose and hemicellulose strongly promotes the formation of 2, 5-diethoxytetrahydrofuran and inhibits the formation of altrose and levoglucosan, while the presence of cellulose enhances the formation of hemicellulose-derived acetic acid and 2-furfural. Pyrolysis characteristics of biomass cannot be predicted through its composition in the main components.     

Thermal degradation processes in aliphatic polydithiocarbonates

The thermal degradation of three aliphatic polythiocarbonates was investigated by direct pyrolysis in the ion source of a mass spectrometer operating both in electron and chemical ionization modes. The overall evidence indicates that these polymers start decomposing at about 250–280°C by an end-biting process initiating from the SH end-groups, which produces a mixture of cyclic sulfides, disulfides, and dithiocarbonates. Another decomposition step is observed at higher temperature (ca. 350–370°C), producing essentially the same compounds evolved in the first stage, but with significant differences in their relative abundances. An intramolecular exchange (back-biting) process is believed to be responsible for the second thermal decomposition stage     

Improving the Sensitivity of Mass Spectrometry by Using a New Sheath Flow Electrospray Emitter Array at Subambient Pressures

Arrays of chemically etched emitters with individualized sheath gas capillaries were developed to enhance electrospray ionization (ESI) efficiency at subambient pressures. By incorporating the new emitter array in a subambient pressure ionization with nanoelectrospray (SPIN) source, both ionization efficiency and ion transmission efficiency were significantly increased, providing enhanced sensitivity in mass spectrometric analyses. The SPIN source eliminates the major ion losses of conventional ESI-mass spectrometry (MS) interfaces by placing the emitter in the first reduced pressure region of the instrument. The new ESI emitter array design developed in this study allows individualized sheath gas around each emitter in the array making it possible to generate an array of uniform and stable electrosprays in the subambient pressure (10 to 30 Torr) environment for the first time. The utility of the new emitter arrays was demonstrated by coupling the emitter array/SPIN source with a time of flight (TOF) mass spectrometer. The instrument sensitivity was compared under different ESI source and interface configurations including a standard atmospheric pressure single ESI emitter/heated capillary, single emitter/SPIN and multi-emitter/SPIN configurations using an equimolar solution of nine peptides. The highest instrument sensitivity was observed using the multi-emitter/SPIN configuration in which the sensitivity increased with the number of emitters in the array. Over an order of magnitude MS sensitivity improvement was achieved using multi-emitter/SPIN compared with using the standard atmospheric pressure single ESI emitter/heated capillary interface. Graphical Abstract

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