Ionic compounds derived from crude glycerol: Thermal energy storage capability evaluation

Ionic liquids (diimidazol-1-ium esters) prepared from wastes, crude glycerol and carboxylic acids are investigated as potential phase change materials (PCM). The ionic liquids (IL) with best thermophysical properties were those with also better production yield (higher than 75%). The chemical composition of those IL was with R1 being (CH3)3CCO, CH3(CH2)14CO or C2H3CO; R2 being BIM+; R3 being BIM+; and X- being 2 Cl‾. Phase change of state (solid-liquid) of this IL was 85 ºC, 264 ºC and 128 ºC, which means potential application in different fields such as domestic hot water, solar cooling and industry, respectively. The measured melting enthalpy 328 kJ/kg, 408 kJ/kg, and 660 kJ/kg is much higher in all cases than the usual found in commercial PCM (100 kJ/kg), therefore, these ILs synthetized in this study are proper candidates to be used as PCM because of the huge amounts of energy that they are able to store and their low cost. Moreover, biobPCM are sustainable materials since its obtaining process is based on oil.The work is partially funded by the Spanish government (ENE2015-64117-C5-1-R (MINECO/FEDER) and CTQ2015-70982-C3-1-R (MINECO/FEDER)). The authors would like to thank the Catalan Government for the quality accreditation given to the research groups GREA (2014 SGR 123), Agricultural Biotechnology (2014 SGR 1296) and DIOPMA (2014 SGR 1543). Dr. Camila Barreneche would like to thank Ministerio de Economia y Competitividad de España for Grant Juan de la Cierva, FJCI-2014-22886.The research leading to these results has received funding from the European Union’s Seventh Framework Program (FP7/2007–2013) under grant agreement n° PIRSES-GA-2013-610692 (INNOSTORAGE) and from the European Union’s Horizon 2020 research and innovation program under grant agreement No 657466 (INPATH-TES)

Digital Twins in Agriculture: Orchestration and Applications

Digital Twins have emerged as an outstanding opportunity for precision farming, digitally replicating in real-time the functionalities of objects and plants. A virtual replica of the crop, including key agronomic development aspects such as irrigation, optimal fertilization strategies, and pest management, can support decision-making and a step change in farm management, increasing overall sustainability and direct water, fertilizer, and pesticide savings. In this review, Digital Twin technology is critically reviewed and framed in the context of recent advances in precision agriculture and Agriculture 4.0. The review is organized for each step of agricultural lifecycle, edaphic, phytotechnologic, postharvest, and farm infrastructure, with supporting case studies demonstrating direct benefits for agriculture production and supply chain considering both benefits and limitations of such an approach. Challenges and limitations are disclosed regarding the complexity of managing such an amount of data and a multitude of (often) simultaneous operations and supports

Synthesis and catalytic studies of nanoalloy particles based on Bismuth, Silver, and Rhenium

The work reports the synthesis and characterization of ternary nanoalloy catalysts of silver, bismuth, and rhenium from alkaline solutions containing L–cysteine as a complexing agent and sodium borohydride as a reducing agent. UV–Vis spectra and dynamic light scattering (DLS) analyses of the obtained colloids were performed. Additionally, high-resolution transmission electron microscope (HR–TEM) analysis assisted the former investigations. The influence of a stabilizer (PVA) was demonstrated for bismuth nanoparticles reaching an average size of 8 nm with PVA, whereas they grew large, 514 nm, in the case of synthesis without stabilizing agent. AgReBi nanoalloy particles reach an average size of 19 nm with PVA. The presence of two absorption maxima in the UV–Vis spectrum suggests shape anisotropy of these nanoparticles. TEM micrographs demonstrate the crystal structure of AgReBi nanoparticles. Cyclic voltamaperometry allows for deciphering of the catalytic properties for hydrogen peroxide electro-reduction. Both bismuth and AgReBi nanoalloy catalysts showed relatively high catalytic activity in H2O2 electro-reduction in the amperometric tests

The Mechanism of Phase Transfer Synthesis of Silver Nanoparticles Using a Fatty Amine as Extractant/Phase Transfer Agent

The paper presents the research results on synthesizing silver nanoparticles in aqueous solutions and their extraction into the organic phase. Studies have shown that it is best to perform the extraction process using n-hexane > cyclohexane > toluene > chloroform > ethyl acetate. The results show a correlation between the dielectric constant of the organic phase and its ability to extract nanoparticles. The lower the dielectric constant is, the higher the extractability. The hydrodynamic radius of the silver nanoparticles changes after transfer to the organic phase, depending greatly on the organic phase used. The extraction mechanism is complex and multi-step. As the first step, the Ag nanoparticles are transferred to the phase boundary. As the second step, the octadecylamine (ODA) molecules adsorb on the silver nanoparticles (AgNPs) surface. The change in particle shape was also noted. This suggests that the interfacial processes are more complex than previously reported. Below the initial concentration of ODA 2 × 10−4 M, the formation of a third phase has been observed. In a one-stage experiment, the concentration of silver nanoparticles after transferring to the organic phase was increased 500 times in about 10 s. The role of the concentration of ODA, therefore, is not only a measure of the extraction efficiency and productivity but functions as an enabler to maintain favorable biphasic processing, which underlines the role of the solvent again

Critical review : ‘Green’ ethylene production through emerging technologies, with a focus on plasma catalysis

Over the years, numerous studies have explored the green synthesis of ethylene. Within this context, the focus of this perspective shifts toward plasma technology, which has demonstrated the capability to convert methane into ethylene. Plasma catalysis creates distinctive physical and chemical environments, particularly at normal temperature and pressure, distinguishing it from alternative methods. Nevertheless, the utilization of atmospheric pressure plasma is intricate, posing scientific challenges in the realms of physics and chemistry. In this viewpoint, various key performance aspects are evaluated, encompassing methane conversion efficiency, ethylene selectivity, and specific energy input. These scientific pros and cons are then assessed for their readiness for industrial-scale implementation. Initially, the potential for small-scale ethylene production is examined, leveraging existing robust process technologies to unlock fresh market and supply chain opportunities. Subsequently, the sustainability of plasma technology for green ethylene production is compared to conventional ethylene production and alternative green ethylene production methods, including biomass-based approaches. Contrary to perhaps optimistic expectations, current literature evidence does not uniformly favor the latter, indicating the potential for plasma-based green ethylene processes. Additionally, this paper underscores the importance of considering Environmental, Social, and Governance factors that influence business decisions. Finally, this review underscores plasma technology as a potentially promising approach for green ethylene synthesis from methane, offering unique advantages under normal conditions while simultaneously presenting scientific challenges. It assesses its viability for small-scale production and benchmarks its sustainability against conventional and alternative methods, emphasizing the importance of a sustainable future for the green petrochemical industry

The mechanism of phase transfer synthesis of silver nanoparticles using a fatty amine as extractant/phase transfer agent

The paper presents the research results on synthesizing silver nanoparticles in aqueous solutions and their extraction into the organic phase. Studies have shown that it is best to perform the extraction process using n-hexane > cyclohexane > toluene > chloroform > ethyl acetate. The results show a correlation between the dielectric constant of the organic phase and its ability to extract nanoparticles. The lower the dielectric constant is, the higher the extractability. The hydrodynamic radius of the silver nanoparticles changes after transfer to the organic phase, depending greatly on the organic phase used. The extraction mechanism is complex and multi-step. As the first step, the Ag nanoparticles are transferred to the phase boundary. As the second step, the octadecylamine (ODA) molecules adsorb on the silver nanoparticles (AgNPs) surface. The change in particle shape was also noted. This suggests that the interfacial processes are more complex than previously reported. Below the initial concentration of ODA 2 × 10−4 M, the formation of a third phase has been observed. In a one-stage experiment, the concentration of silver nanoparticles after transferring to the organic phase was increased 500 times in about 10 s. The role of the concentration of ODA, therefore, is not only a measure of the extraction efficiency and productivity but functions as an enabler to maintain favorable biphasic processing, which underlines the role of the solvent again

Eustress in Space: Opportunities for Plant Stressors Beyond the Earth Ecosystem

Human space exploration cannot occur without reliable provision of nutritious and palatable food to sustain physical and mental well-being. This ultimately will depend upon efficient production of food in space, with on-site manufacturing on space stations or the future human colonies on celestial bodies. Extraterrestrial environments are by their nature foreign, and exposure to various kinds of plant stressors likely cannot be avoided. But this also offers opportunities to rethink food production as a whole. We are used to the boundaries of the Earth ecosystem such as its standard temperature range, oxygen and carbon dioxide concentrations, plus diel cycles of light, and we are unfamiliar with liberating ourselves from those boundaries. However, space research, performed both in true outer space and with mimicked space conditions on Earth, can help explore plant growth from its ‘first principles’. In this sense, this perspective paper aims to highlight fundamental opportunities for plant growth in space, with a new perspective on the subject. Conditions in space are evidently demanding for plant growth, and this produces “stress”. Yet, this stress can be seen as positive or negative. With the positive view, we discuss whether plant production systems could proactively leverage stresses instead of always combatting against them. With an engineering view, we focus, in particular, on the opportunities associated with radiation exposure (visible light, UV, gamma, cosmic). Rather than adapting Earth conditions into space, we advocate on rethinking the whole issue; we propose there are opportunities to exploit space conditions, commonly seen as threats, to benefit space farming

Circular solid state reduction process of fine copper powder synthesis with life cycle assessment for photovoltaics application

This paper presents the process of synthesis of copper powders obtained by the pyrometallurgical method without the participation of the liquid phase. This method is based on the simultaneous decomposition and reduction of copper (II) carbonate. Hydrogen was used as a reducing agent. Due to the strongly exothermic thermal effect of the reduction reaction, a mixture of inert gas and hydrogen was used to better control the parameters. Studies have shown that the carbonate method enables the synthesis of copper powders with a narrow distribution and controlled size. The size is controlled by the grinding time of the copper (II) carbonate. An life cycle assessment and circularity study evaluate the sustainability of the new process, and focus is given to the energy efficiency

Continuous-flow in-line solvent-swap crystallization of vitamin D(3)

A continuous tandem in-line evaporation–crystallization is presented. The process includes an in-line solvent-swap step, suitable to be coupled to a capillary based cooler. As a proof of concept, this setup is tested in a direct in-line acetonitrile mediated crystallization of Vitamin D₃. This configuration is suitable to be coupled to a new end-to-end continuous microflow synthesis of Vitamin D₃. By this procedure, vitamin particles can be crystallized in continuous flow and isolated using an in-line continuous filtration step. In one run in just 1 min of cooling time, ∼50% (w/w) crystals of Vitamin D₃ are directly obtained. Furthermore, the polymorphic form as well as crystals shape and size properties are described in this paper.Marc Escribà-Gelonch, Volker Hessel, Manuel C. Maier, Timothy Noël, Maria Fernanda Neira d’Angelo and Heidrun Gruber-Woelfle

Glicerol en la preparació d'esters de clorohidrina i derivats

Es presenten diferents reaccions de síntesi química, en les quals participa el glicerol com a reactiu, moltes d'elles amb rendiments elevats i bons percentatges de conversió. Un aspecte rellevant d'aquestes reaccions és l'obtenció de compostos o precursors sintètics de substàncies d'alt valor afegit.Així, a partir de la síntesi d'esters de dicloropropil, usant glicerol i clorotrimetilsilà com a font de clor o amb clorur d'alumini usant un líquid iònic, s'han sintetitzat esters d'al·lil, alguns d'ells amb efecte ovicida en insectes. Un dels esters de dicloropropil sintetitzat a partir d'un àcid versàtic ha estat la referència per a la preparació d'esters dessimetritzats usant iodur, hidroxils o imidazoles com a nucleòfils.Amb la finalitat de fer les reaccions més sostenibles, s'han usat reactius provinents de subproductes industrials, tant del sector d'olis i greixos, com de la indústria del biodiesel.S'han emprat noves tècniques en síntesi orgànica, com els líquids iònics i les microones. L'ús de microreactors en una de les reaccions ha demostrat ser efectiu per a disminuir el temps de reacció, la qual cosa hauria de facilitar el seu escalatSe presentan diferentes reacciones de síntesis química en las cuales participa el glicerol como reactivo. La mayoría de ellas presentan altos rendimientos y buenos porcentajes de conversión. Un aspecto relevante de estas reacciones es la obtención mediante síntesis química de compuestos o precursores sintéticos de sustancias de alto valor añadido.Así, a partir de la síntesis de ésteres de dicloropropilo, usando glicerol y clorotrimetilsilano como fuente de cloro, o con cloruro de aluminio usando un líquido iónico, se han sintetizado ésteres de alilo, algunos de ellos con efecto ovicida. Una de los ésteres de dicloropropilo obtenido a partir de un ácido versático se ha usado como referencia para la preparación de ésteres desimetrizados usando ioduro, hidroxilo o imidazole como nucleófilos.Con la finalidad de aumentar la sostenibilidad, se han usado reactivos procedentes de subproductos industriales, tanto del sector de aceites y grasas, como de la industria del biodiesel.Las nuevas tecnologías, como los líquidos iónicos y las microondas, también han sido aplicadas en algunas de las reacciones estudiadas. Por otra parte, el uso de microreactores ha permitido mejorar el tiempo de reacción de uno de los procesos estudiados, hecho que debería facilitar su escalado.Different synthetic reactions are shown, where glycerol is used as a starting material. High yields and conversions are reported in many of the described reactions. One relevant aspect is that compounds or synthetic precursors with high added value can be obtained.Thus, starting from dichloropropyl esters, allyl esters can be obtained, some of them with ovicidal effects. These esters can be synthesised using glycerol and either chlorotrimetylsilane or aluminium chloride as chlorine source. In the later case an ionic liquid is needed. A versatic dichloropropyl ester has been the reference to prepare desymmetrized esters using iodine, hydroxy ion or imidazole derivatives as nucleophilic groups.With the aim to develop sustainable reactions, industrial byproducts from the vegetable oil and fat industries, and from the biodiesel industries have been used as reagents.New technologies, such as ionic liquids and microwaves have also been applied. A continuous process using a microreactor has been developed, which could allow the corresponding reaction to be scaled