Reaction Steps Research Articles

Lysine-coupled fly ash accelerated CO2 mineralization: Feasibility and reaction mechanism

CO2 mineralization using alkaline solid waste is a promising technology for integrated pollution reduction and carbon sequestration. This paper proposed an efficient and environmentally friendly method for lysine-coupled fly ash accelerated CO2 mineralization. And the feasibility of this process was preliminarily explored. The results showed that under mild operating conditions, the promotion of lysine achieved a carbon sequestration capacity of approximately 122.60 g-CO2/kg-FA, with a CO2 mineralization efficiency of 72.84 %. Additionally, lysine acted as a crystal form regulator for CaCO3, resulting in vaterite CaCO3 at an appropriate lysine concentration. Using 13C nuclear magnetic resonance (NMR), the carbamates, bicarbonates/carbonates, and Lys/protonated Lys at different reaction stages were considered to propose a novel reaction mechanism for the Lys-FA-H2O-CO2 system. It indicates that lysine accelerates key reaction steps in the fly ash carbonation process. Lysine, acting as a proton acceptor and promoting carbamate formation, accelerates the mass transfer of CO2 from the gas phase to the liquid phase. Meanwhile, the presence of lysine enhances the leaching capacity of Ca2+ by three times compared to H2O.

Thermal explosion and distribution of hydromagnetic Eyring–Prandtl double exothermic diffusion-reaction fluid in a porous channel

Harmful waste discharge poses a global threat to environmental degradation, as incomplete combustion of hydrocarbons can lead to unusual diseases and natural disasters, as well as toxic discharge. Therefore, this research aims to investigate the thermal explosion and distribution of hydromagnetic Eyring–Prandtl fluid during double exothermic combustion in a porous channel. The working Eyring–Prandtl fluid is assumed to be fully viscoelastic to inspire the combustion process in the absence of material deformation. A partial differential model of an electromagnetic pressure-driven flow is developed to govern the combustion reaction process in the presence of chemical kinetics, non-isothermal fixed wall constraints, and without fluid material reactant consumption. The model is transformed into an invariant form by introducing similarity variables; the resultant dynamical equations are solved via a finite difference semi-implicit scheme. The graphs and tables demonstrate that the rising parameter values for the double reaction step propelled heat transfer to help improve combustion processes. Also, the material dilatant parameter enhanced the fluid viscosity for increased chemical industrial usage which implies that, excessive heat generation due to exothermic combustion must be supervised to circumvent reactant species blowup. In addition, the magnetic field created complex dynamics in the fluid by introducing electromagnetic Lorentz forces, which changed the reaction rate and heat distribution inside the channel. Furthermore, there is a strong positive correlation between the results obtained in the current study and the existing published data.

A Concise Formal Total Synthesis of (±)‐Laurokamurene B and (±)‐β‐Cuparenone

AbstractThe study describes a concise four‐step formal total synthesis of racemic (±)‐laurokamurene B, a sesquiterpene with a rearranged laurene carbon framework. This method also extends to the formal total synthesis of β‐cuparenone. Compared with previously reported laurokamurene B's syntheses, our approach significantly reduces the total number of reaction steps by leveraging the known scaffolds as the key concept. Optimized esterification for the generation of appropriately substituted cinnamate esters, one‐pot polyphosphoric acid (PPA) mediated fragmentation followed by Friedel–Crafts acylation, and intramolecular cyclization led to the efficient construction of pivotal intermediate 3‐arylcyclopent‐2‐en‐1‐one with a quaternary center; subsequent α‐methylation and reductive deoxygenation resulted into the marine natural product (±)‐laurokamurene B. Additionally, β‐methylation and deoxygenation of the obtained key 3‐arylcyclopente‐2‐en‐1‐one intermediate could also serve for the formal total synthesis of (±)‐β‐cuparenone in the shortest approach.

Computational-guided discovery of UDP-glycosyltransferases for lauryl glucoside production using engineered E. coli

Defining suitable enzymes for reaction steps in novel synthetic pathways is crucial for developing microbial cell factories for non-natural products. Here, we developed a computational workflow to identify C12 alcohol-active UDP-glycosyltransferases. The workflow involved three steps: (1) assembling initial candidates of putative UDP-glycosyltransferases, (2) refining selection by examining conserved regions, and (3) 3D structure prediction and molecular docking. Genomic sequences from Candida, Pichia, Rhizopus, and Thermotoga, known for lauryl glucoside synthesis via whole-cell biocatalysis, were screened. Out of 240 predicted glycosyltransferases, 8 candidates annotated as glycosyltransferases were selected after filtering out those with signal peptides and identifying conserved UDP-glycosyltransferase regions. These proteins underwent 3D structure prediction and molecular docking with 1-dodecanol. RO3G, a candidate from Rhizopus delemar RA 99–880 with a relatively high ChemPLP fitness score, was selected and expressed in Escherichia coli BL21 (DE3). It was further characterized using a feeding experiment with 1-dodecanol. Results confirmed that the RO3G-expressing strain could convert 1-dodecanol to lauryl glucoside, as quantified by HPLC and identified by targeted LC-MS. Monitoring the growth and fermentation profiles of the engineered strain revealed that RO3G expression did not affect cell growth. Interestingly, acetate, a major fermentation product, was reduced in the RO3G-expressing strain compared to the GFP-expressing strain, suggesting a redirection of flux from acetate to other pathways. Overall, this work presents a successful workflow for discovering UDP-glycosyltransferase enzymes with confirmed activity toward 1-dodecanol for lauryl glucoside production.Graphical abstract

Molecular Probing Coupled with Density Functional Theory Calculation to Reveal the Influence of Fe Doping on Fe-NiOOH Electrode for High Current Density of Water Splitting.

Fe-doped NiOOH electrocatalysts have attracted wide interest for the exceptional oxygen evolution reaction (OER) performance, but the precise role of Fe doping on the improved intrinsic activity remains unclear. Herein, the molecular probe technique combined with density functional theory calculation is used to reveal the influence of the Fe atom on the rate-determining step of the OER reaction, where the pre-catalyst of hierarchical self-supporting NiFe layered double hydroxide [LDH] nanosheets equipped on nickel foam (NiFe LDH/NF) is generated via a facile and industrially well-matched one-pot corrosion method. The physical characterization results reveal the reconstruction of NiFe LDH into Fe-doped NiOOH for promoted OER, which has a lower OH* adsorption energy with fast subsequent steps that help in obtaining an improved charge injection efficiency compared to NiOOH. In addition, more exposed electroactive species and facile delivery of mass/electron inside the catalytic procedure actually have a high-quality contribution to the outstanding catalytic activity. Therefore, the NiFe LDH36/NF electrocatalyst provides high catalytic activities of 241 and 320mV at 10mA cm-2 toward the OER and overall water-splitting in 1m KOH. This work provides a promising avenue for the rational design of durable self-supporting electrodes toward large-scale water splitting.

Efficient and Ultrastable Seawater Electrolysis at Industrial Current Density with Strong Metal-Support Interaction and Dual Cl--Repelling Layers.

Direct seawater electrolysis is emerging as a promising renewable energy technology for large-scale hydrogen generation. The development of Os-Ni4Mo/MoO2 micropillar arrays with strong metal-support interaction (MSI) as a bifunctional electrocatalyst for seawater electrolysis is reported. The micropillar structure enhances electron and mass transfer, extending catalytic reaction steps and improving seawater electrolysis efficiency. Theoretical and experimental studies demonstrate that the strong MSI between Os and Ni4Mo/MoO2 optimizes the surface electronic structure of the catalyst, reducing the reaction barrier and thereby improving catalytic activity. Importantly, for the first time, a dual Cl- repelling layer is constructed by electrostatic force to safeguard active sites against Cl- attack during seawater oxidation. This includes a strong Os─Cl adsorption and an in situ-formed MoO4 2- layer. As a result, the Os-Ni4Mo/MoO2 catalyst exhibits an ultralow overpotential of 113 and 336mV to reach 500mA cm-2 for HER and OER in natural seawater from the South China Sea (without purification, with 1m KOH added). Notably, it demonstrates superior stability, degrading only 0.37 µV h-1 after 2500 h of seawater oxidation, significantly surpassing the technical target of 1.0 µV h-1 set by the United States Department of Energy.

A Convenient Route to Large-Scale Chemical Synthesis of p-Hydroxyphenylacetaldehyde Oxime and Its p-β-d-Glucopyranoside: Key Intermediates and Products in Plant Specialized Metabolism.

Oximes are unrecognized chameleons in general and specialized plant metabolism. E- and Z-p-hydroxyphenylacetaldehyde oxime are key intermediates in the biosynthesis of the cyanogenic glucoside dhurrin produced in sorghum. Nevertheless, none of the geometrical oxime isomers accumulate in the plant. Herein, we report a convenient route to the chemical synthesis of E- and Z-p-hydroxyphenylacetaldehyde oxime and its biologically produced p-β-d-glucopyranoside using p-hydroxyphenylacetic acid as a starting material. This starting material is also available in radiolabeled forms. All reaction steps proceeded with excellent yield under mild conditions, operational facility, and scalability.

Synthesis of Pyrrolidine‐fused β‐lactams as Potential β‐lactamase Inhibitors

AbstractA synthetic protocol for the preparation of novel 3,4‐pyrrolidine‐fused β‐lactams was developed. The proposed 2,6‐diazabicyclo[3.2.0]heptan‐7‐one scaffolds were constructed through an amido group‐induced, potassium tert‐butoxide‐promoted intramolecular ring closure of 3‐acylamino‐4‐oxiranyl‐β‐lactams as the key reaction step. Alternatively, the desired cyclization was also effected by means of a scandium triflate‐mediated catalytic approach. In this way, a set of stereodefined 3,4‐pyrrolidine‐fused β‐lactams was synthesized, which were preliminary evaluated as β‐lactamase inhibitors. These first‐line biological assessments led to the identification of a 2‐benzoyl‐6‐(4‐methoxyphenyl)‐substituted diazabicyclo structure as an eligible starting point for further β‐lactamase inhibitor optimization studies.

Dilute Pd−Ni Alloy through Low‐temperature Pyrolysis for Enhanced Electrocatalytic Hydrogen Oxidation

AbstractDesigning highly active and cost‐effective electrocatalysts for the alkaline hydrogen oxidation reaction (HOR) is critical for advancing anion‐exchange membrane fuel cells (AEMFCs). While dilute metal alloys have demonstrated substantial potential in enhancing alkaline HOR performance, there has been limited exploration in terms of rational design, controllable synthesis, and mechanism study. Herein, we developed a series of dilute Pd−Ni alloys, denoted as x% Pd−Ni, based on a trace‐Pd decorated Ni‐based coordination polymer through a facile low‐temperature pyrolysis approach. The x% Pd−Ni alloys exhibit efficient electrocatalytic activity for HOR in alkaline media. Notably, the optimal 0.5 % Pd−Ni catalyst demonstrates high intrinsic activity with an exchange current density of 0.055 mA cm−2, surpassing that of many other alkaline HOR catalysts. The mechanism study reveals that the strong synergy between Pd single atoms (SAs)/Pd dimer and Ni substrate can modulate the binding strength of proton (H)/hydroxyl (OH), thereby significantly reducing the activation energy barrier of a decisive reaction step. This work offers new insights into designing advanced dilute metal or single‐atom‐alloys (SAAs) for alkaline HOR and potentially other energy conversion processes.

Dilute Pd-Ni Alloy through Low-temperature Pyrolysis for Enhanced Electrocatalytic Hydrogen Oxidation.

Designing highly active and cost-effective electrocatalysts for the alkaline hydrogen oxidation reaction (HOR) is critical for advancing anion-exchange membrane fuel cells (AEMFCs). While dilute metal alloys have demonstrated substantial potential in enhancing alkaline HOR performance, there has been limited exploration in terms of rational design, controllable synthesis, and mechanism study. Herein, we developed a series of dilute Pd-Ni alloys, denoted as x% Pd-Ni, based on a trace-Pd decorated Ni-based coordination polymer through a facile low-temperature pyrolysis approach. The x% Pd-Ni alloys exhibit efficient electrocatalytic activity for HOR in alkaline media. Notably, the optimal 0.5 % Pd-Ni catalyst demonstrates high intrinsic activity with an exchange current density of 0.055 mA cm-2, surpassing that of many other alkaline HOR catalysts. The mechanism study reveals that the strong synergy between Pd single atoms (SAs)/Pd dimer and Ni substrate can modulate the binding strength of proton (H)/hydroxyl (OH), thereby significantly reducing the activation energy barrier of a decisive reaction step. This work offers new insights into designing advanced dilute metal or single-atom-alloys (SAAs) for alkaline HOR and potentially other energy conversion processes.

Atomically dispersed bimetallic FeZn-N-C with oxidase-like performance: Synthesis, characterization, calculation and activity

The burgeoning interest in single atom catalysts (SACs) stems from their exceptional oxidase-mimicking capabilities, driving substantial advancements in this field. Nevertheless, a critical knowledge gap remains regarding the influence of Zn incorporation on the oxidase-like activity of atomically dispersed Fe-N-C catalysts. This study successfully synthesized and comprehensively characterized three distinct SACs (FeZn SAC-N@C, Fe SAC-N@C, and Zn SAC-N@C) using TEM, HAADF-STEM, XRD, XPS, BET, ICP-MS, and XAFS techniques. Activity assays revealed that FeZn SAC-N@C exhibited the highest oxidase-mimicking activity, with Fe SAC-N@C displaying moderate activity, whereas Zn SAC-N@C did not exhibit oxidase-like behavior. The superior oxidase-like activity of FeZn SAC-N@C is attributed to its enhanced O2 activation capacity, characterized by a high free energy of 0.90 eV in the rate-determining reaction step, surpassing those of Fe SAC-N@C (0.85 eV) and Zn SAC-N@C (0.71 eV). EPR and DFT calculations elucidated the catalytic mechanism of FeZn SAC-N@C, involving the generation of O2− radicals. As a proof-of-concept, FeZn SAC-N@C demonstrates potential as a colorimetric sensor for detecting ascorbic acid and nitrite, achieving a limit of detection of 0.77 μM for ascorbic acid and 0.16 μM for nitrite. These findings open a new avenue for configuring bimetallic atomically dispersed catalysts with oxidase-like activity in future research.

A New Fluorescent Method for Measuring Peroxiredoxin Enzyme Activity Using Monobromobimane.

A novel fluorometric method is presented for accurately quantifying peroxiredoxin (Prx) enzyme activity in vitro. The rate-limiting step in the Prx-catalyzed reaction is the dissociation of peroxide. To avoid interference from catalase, we developed an assay using tert-butyl hydroperoxide (t-BOOH) as a substrate for specific Prx activity measurement. The assay involves incubating the enzyme substrates 1,4-dithio-DL-threitol (DTT) and t-BOOH in a suitable buffer at 37°C for 10min in a known volume of Prx enzyme. Following incubation, the reagent monobromobimane (mBB) is added to terminate the enzymatic reaction and produce a fluorescent product. Prx activity is subsequently determined by measuring thiol fluorescence, with reaction conditions optimized using a Bland-Altman plot. The efficacy of this novel protocol was rigorously validated by comparing Prx activity measurements from paired samples with those generated by a reference assay. A correlation coefficient of 0.995 was observed between the two methods, demonstrating superior precision and reliability compared to existing methods. The mBB-Prx protocol offers a significant safety advantage by using t-BOOH as a substrate for Prx activity measurement. As catalase does not catalyze t-BOOH dissociation, including sodium azide is unnecessary. Moreover, the method obviates the need for concentrated acids to terminate the Prx enzymatic reaction, as the mBB reagent efficiently inhibits Prx activity. This streamlined approach simplifies the assay and significantly improves its safety and usability, providing users with a reliable and convenient tool. The convenience of this method allows users to focus on their research without worrying about safety or complex procedures.

Denitrative Functionalization of Nitroarenes: Recent Progress and Future Perspectives

AbstractNitroarenes are fundamental feedstocks in the chemical industry. Their relatively inert C−NO2 bond allows for late‐stage modifications of molecules and exhibits complete orthogonality to the reactivity of C‐halogen bond in cross‐coupling reactions. The denitrative functionalization of nitroarenes holds significant appeal due to it avoids the use of aryl halides, thereby simplifying reaction steps and improving atom and step economy. Recent progress in direct denitrative functionalization of nitroarenes includes palladium‐catalyzed denitrative coupling, copper‐catalyzed denitrative coupling, as well as metal‐free one‐pot C−NO2 functionalization. In this review, we provide a concise overview of these advancements, detailing the reaction features and mechanisms. This summary aims to highlight the versatility and efficiency of denitrative functionalization methodologies, offering insights into their potential applications and inspiring further research in this promising area of organic synthesis.

Enrichment of Active Hydrogen at Amorphous CoO/Cu2O Heterojunction Interfaces Enhances Electrocatalytic Nitrate Reduction to Ammonia.

The reduction of nitrate into valuable ammonia via electrocatalysis offers a green and sustainable synthetic pathway for ammonia. The electrocatalytic nitrate reduction reaction (NO3RR) encompasses two crucial reaction steps: nitrate deoxygenation and nitrite hydrogenation. Notably, the nitrite hydrogenation reaction is regarded as the rate-determining step of the process. Herein, the amorphous CoO support introduced for the construction of the a-CoO/Cu2O tandem catalyst provides sufficient active hydrogen and synergistically catalyzes the NO3RR. The a-CoO/Cu2O catalyst showed excellent performance with a maximum NH3 Faradaic efficiency of 95.72% and a maximum yield rate of 0.96mmol h-1 mgcat -1 at -0.4V. In the flow cell, the maximum NH3 yield rate of 12.14mmol h-1 mgcat -1 is achieved at -800mA. The high NO3RR activity of a-CoO/Cu2O is attributed to the synergistic cascade effect of amorphous CoO and Cu2O at the heterojunction interface, where Cu2O serves as the adsorption site for NO3 -, while the accelerated active hydrogen generation of amorphous CoO promotes the nitrite hydrogenation reaction. This work provides a strategy for designing multi-site cascade catalysts centered on amorphous structures to achieve efficient NO3RR.

Analysis of Chemical Kinetics of Multistep Reactions by Mean Reaction Time.

Although methods to derive the rate equation from a kinetic model have been known for over a century, it remains mathematically challenging to derive the rate equation for complex reactions involving multiple steps, as the derivation requires a solution for simultaneous differential equations. Furthermore, the derived kinetic equations are often difficult to intuitively understand. Here, we report a radically different approach to analyze chemical kinetics using the mean reaction time, the average of the time required for the completion of a chemical reaction. This mathematical description of chemical kinetics provides an intuitive understanding of how individual steps in a multistep reaction contributes to the overall kinetics. We demonstrate here the step-by-step approach to derive the formula for the mean reaction time from kinetic models. Surprisingly, one can derive the formula for the mean reaction time without solving simultaneous differential equations or using a steady-state approximation. Being an ensemble-averaged value, the mean reaction time cannot describe the distribution of the reaction time of the individual chemical entities. However, the mean reaction time reveals invaluable insights on how the energy levels of the ground states and the transition states affect the kinetics of the multistep reaction. As proof of principle, we apply the mean reaction time to enzyme kinetics and demonstrate that one can readily derive the expressions of the kinetic parameters (k cat/K M and k cat) even without deriving the Michaelis-Menten equation.

Mechanism of methyl elaidate on the thermal oxidation behavior

The effects of cis–trans isomerization on the oxidation products of oleic acid (composites and structure characterization) were investigated. The reduction of thermal oxidation reaction of methyl elaidate (ME) was 6.72 % lower than that of methyl oleate (MO), and the oxidation products (core aldehydes) first increased and then decreased with the prolongation of thermal oxidation time. ME exhibited better oxidation stability than MO in free radicals, hydroperoxides, double bonds, aldehydes, and glycerides. The oxidation products were mainly 11-oxo-9-undecenoate (initial stage) and methyl 9-oxononanoate (later stage), following the free radical chain reaction mechanism. The H8 in double bond was more easily dehydrogenated in the chain initiation stage than H11, followed by the formation of core aldehyde through three intermediates and two transition states each pathway. ME required a higher energy barrier (1.3–13.6 kJ/mol) than MO reaction, making it more difficult for ME to undergo thermal oxidation reaction. The transition state 4 and 5 were rate determining steps of chain initiation reaction and proliferation reaction, respectively. This study was of great significance to further control the formation of these trans fats and their oxidation products.

A MOF@MOF S-scheme Heterojunction with Lewis Acid-Base Sites Synergistically Boosts Cocatalyst-Free CO2 Cycloaddition.

The photocatalytic cycloaddition reaction between CO2 and epoxide is one of the most promising green routes for CO2 utilization, for which high performance photocatalysts are intensely desired. Herein, we have constructed an S-scheme heterojunction of MIL-125@ZIF-67 modified by amino groups, which achieves a cyclic carbonate yield of as high as 99 % without employing any co-catalyst, outperforming the previously reported photocatalysts. In-situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) and in-situ electron paramagnetic resonance (EPR) spectroscopy reveal the important role of photogenerated electron migration from Lewis acid (Co) sites to the O atom of epoxide in triggering its ring-opening (the rate-determining step of CO2 cycloaddition reaction) under the assistance of photogenerated hole. Synergistically and concurrently, the Lewis base (amino groups) sites activate CO2 to CO2*, facilitating the following CO2 cycloaddition. Such a synergistic effect provides a most favorable approach to design efficient heterogeneous photocatalysts with dual/multiple-active sites for CO2 cycloaddition reaction.

Investigation on the Necessity of Low Rates Activation toward Lithium‐Sulfur Batteries

AbstractLow rate activation process is always used in conventional transition metal oxide cathode and fully activates active substances/electrolyte to achieve stable electrochemical performance. However, the related working mechanism in lithium‐sulfur (Li‐ battery is unclear due to the multiple complex chemical reaction steps including the redox of sulfur and the dissolution of polysulfides intermediate. Hence, the influencing mechanism of activation process on Li‐S battery is explored by adopting different current densities of 0.05, 0.2, and 1 C in initial three cycles before long‐term cycling tests at 0.2 C (denoted by 0.05, 0.2, and 1‐battery). 0.05‐battery presents the highest initial capacity in activation process, while 0.2‐battery presents superior electrochemical performances after 150 cycles. The similar trend can be found in more long‐term cycling rates such as 0.02, 0.1, 0.5, and 1 C. Potentiostatically Li2S precipitation test demonstrates that rapid generation of Li2S is achieved at higher current density, and S8‐Li2Sn‐Li2S conversion is accelerated according to Tafel plots. However, interfacial electrochemical and physical characterizations suggest that serious lithium dendrite growth will be induced under high current density. Therefore, considering the reaction kinetics and interfacial properties, low rate activation process is unnecessary when cycling current lower than 1 C for Li‐S battery.

Insights into the hydrogenation reaction degradation mechanisms of lignin model compound using density functional theory methods

Lignin through pyrolysis results in a liquid byproduct that contains a significant proportion of phenolic compounds, which can be subsequently enhanced into aromatic hydrocarbons using hydrogenation methods. To comprehend the reaction mechanism of the lignin hydrogenation process, we conducted theoretical investigations on the hydrogenation reaction process of different phenolic lignin model compounds by theoretical calculation method M06-2X/6–31++G(d,p). Different potential reaction routes were developed for the hydrogenation process of lignin model compounds, and the thermodynamic and kinetic properties of key reaction steps in each pathway were computed. The calculated results indicate that the hydrogenation reaction process of lignin model compounds, the aromatic compound, CH2O, H2O, and CH3OH may be the products that emits firstly in lignin hydrogenation reaction process. And the presence of methoxyl and hydroxyl substituents on the benzene ring does not significantly impact the hydrogenation process of lignin model compounds. Furthermore, the hydrogenation reaction in lignin model compounds exhibits a high energy barrier of approximately 300.0 kJ/mol. Thus, the hydrogenation process of lignin necessitates either appropriate modifications to the depolymerization conditions or the introduction of a catalyst. This work offers a theoretical foundation for advancing the research on lignin of hydrogenation and achieving optimal resource utilization.

Autothermal hydrogen release from liquid organic hydrogen carrier systems

A typical feature that the LOHC technology shares with other types of chemical hydrogen storage is that the release of hydrogen from the carrier requires an input of heat. In many use cases where waste heat from external sources is not available (e.g. in heavy-duty mobility), this is seen as a major drawback. In this paper, we show that autothermal LOHC dehydrogenation offers a very attractive way to overcome this drawback. In detail, we demonstrate autothermal hydrogen release from dicyclohexylmethane using diphenylmethane oxidation to benzophenone as source of heat. The full storage cycle involves benzophenone hydrodeoxygenation to dicyclohexylmethane, dicyclohexylmethane dehydrogenation to diphenylmethane, and diphenylmethane oxidation to benzophenone. We studied both the individual reaction steps using pure feedstocks and the integral cycle in which the intermediates and by-products of each reaction remain in the system for the subsequent reaction step. Although no efforts have yet been made to develop special catalyst materials for this purpose, the results with the applied commercial hydrodeoxygenation (Pd/C), dehydrogenation (Pt on alumina) and partial oxidation (VOx/TiO2) catalysts are already very promising. The storage cycle can be closed with high selectivity and with only minor total oxidation losses. The proposed concept of autothermal LOHC dehydrogenation offers the potential to increase the amount of useable hydrogen from a given amount of charged hydrogen carrier by up to 30%.