New Approaches and Recent Advances on Characterization of Chemical Functional Groups and Structures,Physiochemical Property,and Nutritional Values in Feedstocks and By-Products: Advanced Spectroanalytical and Modeling Investigations

Abstract: Molecular spectroscopy technique, a rapid and noninvasive analytical technique, is able to reveal biomaterials’ structural features. However, to date, this technique is seldom used in the biofuel and bioethanol processing industry. This article aims to provide research progress and updates on molecular spectroscopy of feedstocks and coproducts from biofuel/bioethanol processing and to show how to use this molecular technique to study the molecular structure, chemical functional groups, and physiochemical properties of feedstocks and coproducts from biofuel processing and how structural changes affect nutrient availability.     

Bioelectrocatalytic Activity of Immobilized Alcohol Oxidase on 4‐(pyrrole‐1‐yl) Benzoic Acid Modified Carbon Nanotubes

A novel bioelectrocatalytic system was prepared by immobilizing alcohol oxidase (AOx) onto multiwalled carbon nanotubes (MWCNT) modified with 4‐(pyrrole‐1‐yl) benzoic acid (PyBA). Functional carboxylic groups from PyBA create covalent amide linkages with amine groups from the enzyme molecule and provide an anchor for the effective immobilization of AOx improving the stability of the whole system. The immobilized enzyme displayed a pair of reversible redox peaks of flavin adenine dinucleotide (FAD) cofactor with the formal potential E^0’=?0.451 V. The response showed a surface‐controlled electrode process with the heterogeneous electron transfer rate constant k_s=2.7 s^?1. Under aerobic conditions AOx(FADH₂) can be oxidized to AOx(FAD) by oxygen, which then reacts with ethanol decreasing the cathodic response, which could be used for ethanol detection with a high sensitivity 13.1 μA mM^?1 cm^?2. The lack of bioactivity towards ethanol in anaerobic conditions suggests the presence of two types of AOx molecules in the system: active with oxygen maintaining the direct electron transfer feature and not active without a redox mediator, due to the deeply embedded FAD cofactor. The polarization curve showed that the electrooxidation current of ethanol appears at ?410 mV and reaches 2.0 µA cm^?1 at ?300 mV. In this case, the bioactivity of AOx to ethanol can be observed offering promising solution for the development of mediatorless systems for application to biosensors and biofuel cells.     

The Open Circuit Voltage in Biofuel Cells: Nernstian Shift in Pseudocapacitive Electrodes

In the development of biofuel cells great effort is dedicated to achieving outstanding figures of merit, such as high stability, maximum power output, and a large open circuit voltage. Biofuel cells with immobilized redox mediators, such as redox polymers with integrated enzymes, show experimentally a substantially higher open circuit voltage than the thermodynamically expected value. Although this phenomenon is widely reported in the literature, there is no comprehensive understanding of the potential shift, the high open circuit voltages have not been discussed in detail, and hence they are only accepted as an inherent property of the investigated systems. We demonstrate that this effect is the result of a Nernstian shift of the electrode potential when catalytic conversion takes place in the absence or at very low current flow. Experimental evidence confirms that the immobilization of redox centers on the electrode surface results in the assembled biofuel cell delivering a higher power output because of charge storage upon catalytic conversion. Our findings have direct implications for the design and evaluation of (bio)fuel cells with pseudocapacitive elements.     

Development of two‐dimensional gas chromatography (GC×GC) coupled with Orbitrap‐technology‐based mass spectrometry: Interest in the identification of biofuel composition

Comprehensive gas chromatography (GC) has emerged in recent years as the technique of choice for the analysis of volatile and semivolatile compounds in complex matrices. Coupling it with high‐resolution mass spectrometry (MS) makes a powerful tool for identification and quantification of organic compounds. The results obtained in this study showed a significant improvement by using GC×GC‐EI‐MS in comparison with GC‐EI‐MS; the separation of chromatogram peaks was highly improved, which facilitated detection and identification. However, the limitation of Orbitrap mass analyzer compared with time‐of‐flight analyzer is the data acquisition rate; the frequency average was about 25 Hz at a mass resolving power of 15.000, which is barely sufficient for the proper reconstruction of the narrowest chromatographic peaks. On the other hand, the different spectra obtained in this study showed an average mass accuracy of about 1 ppm. Within this average mass accuracy, some reasonable elemental compositions can be proposed and combined with characteristic fragment ions, and the molecules can be identified with precision. At a mass resolving power of 7.500, the scan rate reaches 43 Hz and the GC×GC‐MS peaks can be represented by more than 10 data points, which should be sufficient for quantification. The GC×GC‐MS was also applied to analyze a cellulose bio‐oil sample. Following this, a highly resolved chromatogram was obtained, allowing EI mass spectra containing molecular and fragment ions of many distinct molecules present in the sample to be identified.     

An Air‐breathing Carbon Cloth‐based Screen‐printed Electrode for Applications in Enzymatic Biofuel Cells

We report a prototype air‐breathing carbon cloth‐based electrode that was fabricated starting from a commercially available screen‐printed electrode equipped with a transparent ITO working electrode (DropSens, ref. ITO10). The fabrication of the air‐breathing electrodes is straightforward, shows satisfactory reproducibility and a good electrochemical response as evaluated by means of [Fe(CN)₆]^3?/4? voltammetry. The gas‐diffusion electrodes were successfully modified with the O₂ reducing enzyme bilirubin oxidase from Myrothecium verrucaria in a direct electron transfer regime. The enzyme modified electrodes showed a remarkable high current density for O₂ reduction in passive air‐breathing mode of up to 5 mA cm^?2. Moreover, the enzyme modified electrodes were applied as O₂ reducing biocathodes in a glucose/air enzymatic biofuel cell in combination with a high current density glucose oxidase/redox polymer bioanode. The biofuel cell provides a high maximum power density of (0.34±0.02) mW cm^?2 at 0.25 V. The straightforward design, low cost and the high reproducibility of these electrodes are considered as basis for standardized measurements under gas‐breathing conditions and for high throughput screening of gas converting (bio‐)catalysts.     

Automatic mechanism generation for the combustion of advanced biofuels: A case study for diethyl ether

Advanced biofuels have the potential to supplant significant fractions of conventional liquid fossil fuels. However, the range of potential compounds could be wide depending on selected feedstocks and production processes. Not enough is known about the engine relevant behavior of many of these fuels, particularly when used within complex blends. Simulation tools may help to explore the combustion behavior of such blends but rely on robust chemical mechanisms providing accurate predictions of performance targets over large regions of thermochemical space. Tools such as automatic mechanism generation (AMG) may facilitate the generation of suitable mechanisms. Such tools have been commonly applied for the generation of mechanisms describing the oxidation of non-oxygenated, non-aromatic hydrocarbons, but the emergence of biofuels adds new challenges due to the presence of functional groups containing oxygen. This study investigates the capabilities of the AMG tool Reaction Mechanism Generator for such a task, using diethyl ether (DEE) as a case study. A methodology for the generation of advanced biofuel mechanisms is proposed and the resultant mechanism is evaluated against literature sourced experimental measurements for ignition delay times, jet-stirred reactor species concentrations, and flame speeds, over conditions covering φ = 0.5–2.0, P = 1–100 bar, and T = 298–1850 K. The results suggest that AMG tools are capable of rapidly producing accurate models for advanced biofuel components, although considerable upfront input was required. High-quality fuel specific reaction rates and thermochemistry for oxygenated species were required, as well as a seed mechanism, a thermochemistry library, and an expansion of the reaction family database to include training data for oxygenated compounds. The final DEE mechanism contains 146 species and 4392 reactions and in general, provides more accurate or comparable predictions when compared to literature sourced mechanisms across the investigated target data. The generation of combustion mechanisms for other potential advanced biofuel components could easily capitalize on these database updates reducing the need for future user interventions.     

Preparation,Characterization and Electrochemical Application of Graphene‐metallic Nanocomposites

Three different Graphene‐Metallic (Graphene‐Me) nanocomposites – Graphene‐Silver (Graphene‐Ag), Graphene‐Gold (Graphene‐Au) and Graphene‐Platinum (Graphene‐Pt) nanocomposites – were prepared and characterized. The electrochemical performances of these nanocomposites were tested by incorporating them with glassy carbon paste electrode (GCPE) and used them in biofuel cells (BFC) and as amperometric xanthine biosensor transducers. Present work contains the first application of Graphene‐Au and Graphene‐Ag nanocomposite in BFCs and also first application of these Graphene‐Me nanocomposites in xanthine biosensors. Considering BFC, power and current densities were calculated as 2.03 µW cm^?2 and 167.46 µA cm^?2 for the plain BFC, 3.39 µW cm^?2 and 182.53 µA cm^?2 for Graphene‐Ag, 4.43 µW cm^?2 and 230.15 µA cm^?2 for Grapehene‐Au and 6.23 µW cm^?2 and 295.23 µA cm^?2 for Graphene‐Pt nanocomposite included BFCs respectively. For the amperometric xanthine biosensor linear ranges were obtained in the concentration range between 5 µM and 50 µM with the RSD (n=3 for 30 µM xanthine) value of 4.28 % for plain xanthine biosensor, 3 µM and 50 µM with the RSD (n=3 for 30 µM xanthine) value of 9.37 % for Graphene‐Ag, 5 µM to 20 µM with the RSD (n=3 for 5 µM xanthine) value of 9.00 % and 30 µM to 70 µM with the RSD (n=3 for 30 µM xanthine) value of 8.80 % for Grapehene‐Au and 1 µM and 70 with the the RSD (n=3 for 30 µM xanthine) value of 2.59 % for Grapehene‐Pt based xanthine biosensors respectively.     

由生物质合成高密度喷气燃料

高密度喷气燃料是为先进航空航天飞行器而合成的燃料,以生物质基原料制备高密度喷气燃料符合国家可持续发展战略并可拓展燃料来源。本文综述了近年来由生物质基原料制备高密度喷气燃料的研究进展,燃料种类包括链烷烃、带支链的单环烷烃以及多环烷烃,燃料合成原料包括环酮（醇）、呋喃醛（醇）、芳香族含氧化合物（苯酚、苯甲醚、愈创木酚）、蒎烯等生物质及其平台化合物。发动机的推进性能高度依赖于所用燃料的性能,其中,最重要的性能是密度和低温性能。本文总结了典型燃料的性能以讨论分子结构的影响,增加燃料分子中环的个数会增加燃料密度但是也会导致低温性能不期望的变化,引入支链可改善低温性能。同时讨论了烷基化、缩合、加成、加氢脱氧等燃料合成反应涉及的催化剂、反应机理及其调控等关键因素,最后对由生物质基原料合成高密度喷气燃料的发展趋势进行了展望。本文将有助于探索及发展高密度燃料合成的方法及工艺。     

Applying Co3O4@nanoporous Carbon to Nonenzymatic Glucose Biofuel Cell and Biosensor

A novel hierarchically nanoporous carbon (NPC) derived from Al‐based porous coordination polymer is prepared by two‐step carbonization method for immobilization of the Co₃O₄ in the application of the nonenzymatic biofuel cells and biosensors. The structure and morphology are characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM), high‐resolution transmission electron microscopy (HRTEM), and X‐ray diffraction (XRD). Brunauer‐Emmett‐Teller (BET) is to characterize the porous nature of the NPC, and X‐ray photoelectron spectroscopy (XPS) is to characterize the composition of Co₃O₄@nanoporous carbon (Co₃O₄@NPC). Without collapse in the high carbonization temperature (above 1600 °C), the NPC maintains the nanoporous structure and high specific surface area of 1551.2 m² g⁻¹. In addition, the NPC is composited with Co₃O₄ by hydrothermal method to form the Co₃O₄@NPC. When tested as the nonenzymatic electrocatalyst for glucose oxidation reaction (GOR), the Co₃O₄@NPC exhibits higher response to glucose, in which the current shifts up by 64 %, than pure Co₃O₄ in 0.1 M KOH. The limit of detection is 0.005 mM (S/N=3) and response time is within 3 s. The detection range can be divided into two sections of 0.02–1.4 mM and 1.4–10.7 mM with the sensitivity of 249.1 μA mM⁻¹ cm⁻² and 66.6 μA mM⁻¹ cm⁻², respectively. A glucose fuel cell is constructed with the Co₃O₄@NPC as the anode and Pt/C catalyst as the cathode. The open‐circuit potential of the nonenzymatic glucose/O₂ fuel cell was 0.68 V, with a maximum power density of 0.52 mW cm⁻² at 0.27 V. This work may contribute to exploring other nanoporous carbons for application in glucose fuel cells and biosensors.     

Integrated, electrically contacted NAD(P)+-dependent enzyme-carbon nanotube electrodes for biosensors and biofuel cell applications

Integrated, electrically contacted beta-nicotinamide adenine dinucleotide- (NAD(+)) or beta-nicotinamide adenine dinucleotide phosphate- (NADP(+)) dependent enzyme electrodes were prepared on single-walled carbon nanotube (SWCNT) supports. The SWCNTs were functionalized with Nile Blue (1), and the cofactors NADP(+) and NAD(+) were linked to 1 through a phenyl boronic acid ligand. The affinity complexes of glucose dehydrogenase (GDH) with the NADP(+) cofactor or alcohol dehydrogenase (AlcDH) with the NAD(+) cofactor were crosslinked with glutaric dialdehyde and the biomolecule-functionalized SWCNT materials were deposited on glassy carbon electrodes. The integrated enzyme electrodes revealed bioelectrocatalytic activities, and they acted as amperometric electrodes for the analysis of glucose or ethanol. The bioelectrocatalytic response of the systems originated from the biocatalyzed oxidation of the respective substrates by the enzyme with the concomitant generation of NAD(P)H cofactors. The electrocatalytically mediated oxidation of NAD(P)H by 1 led to amperometric responses in the system. Similarly, an electrically contacted bilirubin oxidase (BOD)-SWCNT electrode was prepared by the deposition of BOD onto the SWCNTs and the subsequent crosslinking of the BOD units using glutaric dialdehyde. The BOD-SWCNT electrode revealed bioelectrocatalytic functions for the reduction of O(2) to H(2)O. The different electrically contacted SWCNT-based enzyme electrodes were used to construct biofuel cell elements. The electrically contacted GDH-SWCNT electrode was used as the anode for the oxidation of the glucose fuel in conjunction with the BOD-SWCNT electrode in the presence of O(2), which acted as an oxidizer in the system. The power output of the cell was 23 muW cm(-2). Similarly, the AlcDH-SWCNT electrode was used as the anode for the oxidation of ethanol, which was acting as the fuel, with the BOD-SWCNT electrode as the cathode for the reduction of O(2). The power output of the system was 48 microW cm(-2).