Metal-Catalyst-Free Growth of Patterned Graphene on SiO2 Substrates by Annealing Plasma-Induced Cross-Linked Parylene for Optoelectronic Device Applications

Eco-Friendly Biomass-Based Carbon Dots, Carbon Nanotubes, Graphene, and Their Derivatives for Enhanced Oil Recovery: A New Horizon for Petroleum Industry

Oil extraction from reservoirs has never been easy, particularly when easily accessible oil sources run out. Enhanced oil recovery (EOR) is a dynamic area of petroleum engineering that seeks to maximize the quantity of crude oil that can be retrieved from an oil field. Researchers and oil producers have emphasized assessing tertiary-stage recovery approaches, such as chemical EOR (CEOR), due to the problems posed by the diverse carbonate rocks. Polymers and surfactants used in CEOR procedures have the potential to harm formation and contaminate the environment. The environmentally beneficial "green enhanced oil recovery" (GEOR) technique includes infusing green fluids to raise tertiary oil output and boost macroscopic and microscopic sweep efficiency, ensuring sustainable practices while minimizing environmental concerns. Utilizing eco-friendly carbon nanomaterials such as biomass-based carbon dots (CDs), carbon nanotubes (CNTs), graphene, and their derivatives for EOR and reservoir monitoring applications represents a promising frontier in the petroleum industry. These particles are pricey and do not extend to GEOR but have been successfully tested in EOR. This innovative approach capitalizes on the unique properties of these nanomaterials to improve the efficiency and sustainability of oil extraction processes. This review aims to explore biomass-derived carbon nanoparticles and investigate their possible functions in GEOR. Furthermore, the use of carbon particles in the GEOR approach is still poorly understood; thus, there needs to be a lot of credentials. The effectiveness, sustainability, and environmental responsibility of petroleum production operations can be enhanced by incorporating carbon nanomaterials from biomass into enhanced oil recovery systems. An environmentally friendly and more resilient energy future may be possible if research and development in this area are allowed to continue. This might completely change how oil resources are found and used.

Evolution of Graphene Patterning: From Dimension Regulation to Molecular Engineering

The realization that nanostructured graphene featuring nanoscale width can confine electrons to open its bandgap has aroused scientists' attention to the regulation of graphene structures, where the concept of graphene patterns emerged. Exploring various effective methods for creating graphene patterns has led to the birth of a new field termed graphene patterning, which has evolved into the most vigorous and intriguing branch of graphene research during the past decade. The efforts in this field have resulted in the development of numerous strategies to structure graphene, affording a variety of graphene patterns with tailored shapes and sizes. The established patterning approaches combined with graphene chemistry yields a novel chemical patterning route via molecular engineering, which opens up a new era in graphene research. In this review, the currently developed graphene patterning strategies is systematically outlined, with emphasis on the chemical patterning. In addition to introducing the basic concepts and the important progress of traditional methods, which are generally categorized into top-down, bottom-up technologies, an exhaustive review of established protocols for emerging chemical patterning is presented. At the end, an outlook for future development and challenges is proposed.

A Review of Graphene: Material Synthesis from Biomass Sources

Single-atom-thick graphene is a particularly interesting material in basic research and applications owing to its remarkable electronic, mechanical, chemical, thermal, and optical properties. This leads to its potential use in a multitude of applications for improved energy storage (capacitors, batteries, and fuel cells), energy generation, biomedical, sensors or even as an advanced membrane material for separations. This paper provided an overview of research in graphene, in the area of synthesis from various sources specially from biomass, advanced characterization techniques, properties, and application. Finally, some challenges and future perspectives of graphene are also discussed.

Asymmetric Response Optoelectronic Device Based on Femtosecond-Laser-Irradiated Perovskite

We have explored an asymmetric optoelectronic response of an FAPb(I_0.8Br_0.2)₃ (FA = formamidine) perovskite device irradiated by a femtosecond (fs) laser at different laser-fluence values. Photoluminescence (PL) spectra indicated a blue shift from 772 nm (1.606 eV) to 745 nm (1.664 eV) and more than 80% quenching of the irradiated perovskite. The blue shift of the PL spectra can be attributed to compositional variation, which was confirmed through elemental analysis and X-ray diffraction. Two distinct characteristic time constants 193-46 ps and 1.9-0.61 ns were obtained by using fs transient absorption spectroscopy. The fast one represents recombination at the interface, whereas the slow one represents band-to-band recombination in the interior of the grain. Interestingly, after the perovskite was irradiated by a femtosecond laser with an appropriate laser fluence (0.135 J/cm²), an asymmetric I-V characteristic was achieved, which should result from irreversible electric domain deflection. Due to the electron-phonon scattering induced by defects, the degree of asymmetry was sensitive to the illumination power. As the photosensitive asymmetric I-V characteristics have a bearing on its photoelectric properties, the findings would be of value in photodiode, memory, and other photoelectric devices.