Novel and Extremely Sensitive NiAlO-NiO Nanostructures on an ITO Sensing Electrode for Enhanced Detection of Ascorbic Acid.

The current study focused on the design of an extremely sensitive electrochemical sensor of ascorbic acid based on a mixture of NiAlO-NiO nanoparticles that, produced in a single step using the sol-gel method, on an ITO electrode. This new sensing platform is useful for the detection of ascorbic acid with a wide range of concentrations extending from the attomolar to the molar. SEM micrographs show the porous structure of the NiAlO-NiO sample, with a high specific surface area, which is beneficial for the catalytic performance of the nanocomposite.

Pyrolysis of tea and coffee wastes: effect of physicochemical properties on kinetic and thermodynamic characteristics.

Unlabelled: Physicochemical properties, kinetic pyrolysis and thermodynamic study of spent green tea, pure spent coffee grounds, spent coffee grounds blended with 50% torrefied barley and coffee husk were experimentally investigated using thermogravimetric analysis under an inert atmosphere to evaluate their thermochemical application. Five isoconversional methods were applied to determine effective activation energy ( ) of the pyrolysis processes. All methods showed good agreement by determining fluctuating values (150-500 kJ mol).

The assessment of buildings and constructions sector of economy proposal: an environmental perspective.

Environmental impact assessment methods suffer from an applicability issue which could impede their use and development. The main subject of this article is to present a method to evaluate the applicability of building environmental assessment method in a given country. Here, when we say that a method is applicable in a given country, it means that it could be widely used and that it could produce the expected effects in terms of energy savings, environmental impact minimization, economic gain, etc.

Municipal sewage sludge energetic conversion as a tool for environmental sustainability: production of innovative biofuels and biochar.

In this study, municipal sewage sludge (MSS) is converted simultaneously into renewable biofuels (bio-oil, syngas) and high value-added products (biochar) using a fixed bed pyrolyzer. This work examines the combined effect of two factors: final pyrolysis temperature (°C) and MSS moisture content (%) on pyrogenic product yields and characteristics. A centered composite experimental design (CCD) is established for pyrolysis process optimization by adopting the response surface methodology (RSM).

Analysis of Minerals and Heavy Metals Using ICP-OES and FTIR Techniques in Two Red Seaweeds (Gymnogongrus griffithsiae and Asparagopsis taxiformis) from Tunisia.

In this study, the mineral and heavy metals (arsenic (As), cadmium (Cd), copper (Cu), iron (Fe), mercury (Hg), potassium (K), manganese (Mn), sodium (Na), phosphorus (P), and lead (Pb)) in two red Tunisian seaweeds Gymnogongrus griffithsiae (G. griffithsiae) and Asparagopsis taxiformis (A. taxiformis), were evaluated.

Modeling kinetics and transport phenomena during multi-stage tire wastes pyrolysis using Comsol®.

This paper is devoted to the modeling of the pyrolysis process in order to predict mass and heat loss profiles of a used tire sample and ultimately prevent eventual difficulties in pyrolysis reactors. Once assumptions are made, the thermal balances and kinetics of each reaction were written. The resolution of the differential equations allowed us to present the profile of heat variation within the sample as a function of temperature in a fixed bed reactor.

Optimization of Hydrothermal and Diluted Acid Pretreatments of Tunisian (L.) Fibers for 2G Bioethanol Production through the Cubic Central Composite Experimental Design CCD: Response Surface Methodology.

This paper opens up a new issue dealing with (LC) lignocellulosic biomass recovery in order to produce 2G bioethanol. LC fibers are composed of three principal fractions, namely, -cellulose (45.80%  ± 1.

Enhancement of biofuels production by means of co-pyrolysis of Posidonia oceanica (L.) and frying oil wastes: Experimental study and process modeling.

Energy recovery from lignocellulosic solid marine wastes, Posidonia oceanica wastes (POW) with slow pyrolysis responds to the growing trend of alternative energies as well as waste management. Physicochemical, thermogravimetric (TG/DTG) and spectroscopic (FTIR) characterizations of POW were performed. POW were first converted by pyrolysis at different temperatures (450°C, 500°C, 550°C and 600°C) using a fixed-bed reactor.