Piotr Krawczyk

Sapindus saponins’ impact on hydrocarbon biodegradation by bacteria strains after short- and long-term contact with pollutant

The introduction of high toxicity petroleum contaminants to the natural environment causes damage to ecosystems and the aesthetics of the surroundings. Therefore it is critical to enhance microbial community performance to manage the degradation process. This paper analyses the effect of natural surfactants from the tree Sapindus mukorossi on biodegradation of hydrocarbons. Analysis of cell surface hydrophobicity and zeta potential confirmed effective modifications of the cell surface parameters essential for the bioavailability of contaminants to microorganisms. Interestingly, favorable differences were observed only for microorganisms from non-contaminated soil. There was also recorded an increase in diesel oil biodegradation to 41% for Sphingomonas sp. and 56% for Pseudomonas alcaligenes on addition of 100mgL(-1) of Sapindus saponins. The addition of natural surfactants has no significant impact on bacterial strains isolated from long-term contaminated soil. This research demonstrates that the addition of Sapindus extract could be a useful tool to improve the effectiveness of microbial degradation of hydrocarbon pollutants by environmental strains in recently contaminated.

Graphene material preparation through thermal treatment of graphite oxide electrochemically synthesized in aqueous sulfuric acid

The present work demonstrates a simple and low-cost method to produce bulk quantities of graphene material through the thermal treatment of graphite oxide (GO). GO of a high oxidation degree was synthesized by electrochemical overoxidation of natural graphite in 11 M H2SO4 using linear sweep voltammetry (LSV) technique. The thus synthesized GO was thermally exfoliated-reduced at 500 °C in air, giving the final product – thermally reduced graphite oxide (TRGO). It should be emphasized that the process of TRGO formation from electrochemically obtained GO is for the first time described in the present work. Due to shock treatment, the BET specific surface area of TRGO increased from 4 to 455 m2 g−1. Additionally, a decrease in the concentration of oxygen functionalities was also observed. Thermal stability of electrochemically synthesized GO was investigated by thermogravimetric analysis (TGA). In order to characterize the synthesized TRGO, investigations by X-ray diffraction (XRD), Raman spectroscopy, X-ray photoelectron spectroscopy (XPS) and scanning electron microscopy (SEM) were performed.

Graphene material prepared by thermal reduction of the electrochemically synthesized graphite oxide

In the present work we demonstrate a simple and effective way to produce bulk quantities of graphene material. For the first time, graphite oxide (GO), synthesized by electrochemical treatment of natural graphite in HClO4 aqueous solution, was used to obtain thermally exfoliated-reduced graphite oxide (TRGO). Herein, GO was thermally exfoliated and reduced at 500 °C in air, giving the final product of TRGO. Due to shock treatment, the volume of the synthesized TRGO drastically increased compared to the starting GO. Furthermore, the exfoliation process resulted in a significant decrease in the concentration of oxygen functionalities. The choice of GO exfoliation temperature was preceded by thermogravimetric analysis (TGA). TRGO was characterized using X-ray diffraction (XRD), Raman spectroscopy, X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM) and atomic force microscopy (AFM) analysis.

Influence of expanded graphite coming from the electrochemical oxidation of phenol on cement-polymer matrix

Abstract In presented article the polymer-modified cement mortars with expanded graphite covered by the oligomer film, being a by-product of phenol electro-oxidation, were investigated. The changes in the morphology of EG and EG/oligomer as well as in the microstructure of cement-polymer composites modified with EG/oligomer were verified using the scanning electron microscopy (SEM). The evaluation of adhesion between EG/oligomer and cement-polymer mortar based on the mechanical tests, especially their flexural behavior. It was shown that the oligomer film formed on EG surface made graphite flakes more durable and resistant to bending. Moreover, the oligomer due to the interaction with polymer network in cement-polymer mortar led to the improvement of flexural toughness of composite.

Regeneration of expanded graphite electrodes by joined electrochemical and ozone treatment in liquid phase

The researches presented in this work were devoted to electrochemico-chemical regeneration of exhausted electrode made of expanded graphite (EG). The aimed process was conducted by electrochemical treatment and ozone flow performed together in wet environment. EG was covered with insoluble products of incomplete oxidation of phenol formed during cyclic voltammetry measurement. The same electrochemical technique was applied for evaluation of regeneration efficiency. To understand the process of EG regeneration, the electrode was characterized by calculating of BET surface, FTIR and XPS analysis. Moreover, SEM images of the investigated samples were also done. Obtained results have showed the success of regeneration treatment, which led to significant enhancement of electrode activity compared to original EG. The present work also revealed that the mechanism of phenol electrooxidation is changed after the regeneration treatment of electrode material. This effect is probably caused by the modification of chemical composition of EG surface due to its interactions with OH radicals intensively generated during the process of regeneration.

Preparation and electrochemical properties of EG/Fe2O3/C composite

The present paper deals with the studies concerning electrochemical properties of the expanded graphite/iron oxide/carbon (EG/Fe2O3/C) composite produced by deep cathodic reduction. The electrochemical activity of EG/Fe2O3/C composite was investigated in alkaline solution by cyclic voltammetry technique. Electrochemical features of EG/Fe2O3/C were found to be strongly influenced by the conditions under which the measurements were performed. The interpretation of electrochemical measurements was supported by the scanning electron microscope (SEM) observation revealing the appearance of carbon fibers of a different diameter as the main component of the carbon layer within the examined EG/Fe2O3/C composite. The X-ray diffraction (XRD) and energy dispersive spectrometry (EDS) analysis have confirmed the presence of Fe2O3 layer within the EG/Fe2O3/C composite. Additionally, the latter analysis has provided information on changes within the chemical composition of EG/Fe2O3/C caused by electrochemical treatment.