We report a unique naturally derived activated carbon with optimally incorporated nitrogen functional groups and ultra-microporous structure to enable high CO 2 adsorption capacity. The coprocessing of biomass (Citrus aurantium waste leaves) and microalgae (Spirulina) as the N-doping agent was investigated by probing the parameter space (biomass/microalgae weight ratio, reaction temperature, and reaction time) of hydrothermal carbonization and activation process (via the ZnCl 2 /CO 2 activation) to generate hydrochars and activated carbons, respectively, with tunable nitrogen content and pore sizes. The central composite-based design of the experiment was applied to optimize the parameters of the prehydrothermal carbonization procedure resulting in the fabrication of N-enriched carbonaceous products with the highest possible mass yield and nitrogen content. The resulting hydrochars and activated carbon samples were characterized using elemental analysis, X-ray diffraction, Fourier transform infrared spectroscopy, X-ray photoelectron spectroscopy, field emission scanning electron microscopy, and Brunauer−Emmett−Teller surface area analysis. We observe that while N-doping and the activation process can individually enhance the CO 2 adsorption capacity to some extent, it is the combined effect of the two processes that synergistically work to greatly increase the adsorption capacity of the N-doped activated carbon by an amount which is more than the sum of individual contributions. We analyze the origins of this synergy with both physical and chemical characterization techniques. The resulting naturally derived activated carbon demonstrates one of the highest CO 2 adsorption capacities (8.43 mmol/g) with rapid adsorption kinetics and good selectivity and reusability.
In this work, design of experiments–response
surface methodology (RSM) was implemented to predict the importance
of hydrothermal carbonization (HTC) key parameters and their interactions
in the preparation of canola-stalk-derived hydrochar via HTC technique.
According to the RSM results, temperature and reaction time were found
to be the most important control factors. The possible optimum conditions
were found to be 207 °C and 82 min for temperature and time,
respectively, in order to achieve a hydrochar with the maximum mass
yield (solid yield 53.38%), carbon recovery rate (52.66), and O/C
ratio (0.69). Furthermore, the optimized hydrochar was successfully
activated via potassium hydroxide (KOH), under mild activation conditions.
Synthesized microporous activated carbon demonstrated the highly improved
Brunauer–Emmett–Teller (BET) surface area of 474.87
m2 g–1 compared to the low BET surface
area of mesoporous hydrochar (S
BET of
2.69 m2 g–1). Porous activated carbon
was used as an adsorbent for methylene blue removal that showed a
promising dye removal capacity of 93.4 mg g–1. The
morphological and chemical compositions of the solid materials were
analyzed by various techniques, including elemental analysis, field
emission scanning electron microscopy (FESEM), BET analysis, Fourier
transform infrared (FTIR) spectroscopy, and energy-dispersive X-ray
spectroscopy.
Carbon dots are zero-dimensional nanomaterials that have garnered significant research interest due to their distinct optical properties, biocompatibility, low fabrication cost, and eco-friendliness. Recently, their light-to-heat conversion ability has led to several novel photothermal applications. In this minireview, we categorize and describe the photothermal application of carbon dots along with methods incorporated to enhance their photothermal efficiency. We also discuss the possible mechanisms by which the photothermal effect is realized in these carbon-based nanoparticles. Taken together, we hope to provide a comprehensive landscape highlighting several promising research directions for using carbon dots for photothermal applications.
Fused deposition modeling (FDM) 3D printing not only
offers numerous
advantages over traditional manufacturing methods but also produces
a significant amount of waste in the form of failed prints, support
structures, and unused filaments. Thus, there is a need to develop
novel and sustainable materials to replace conventional FDM filaments.
We report a unique biomass (waste leaves)-derived activated carbon
that can be infused with polyethylene terephthalate glycol (PETG)
to fabricate a sustainable, cost-effective, and eco-friendly class
of 3D printing filaments that enable 3D printing of parts with superior
mechanical properties. We investigate the key parameters that influence
the chemical, morphological, thermal, surface, and mechanical properties
of our biomass-derived hydrochar, activated carbon, and PETG composite
filaments. The resulting samples are characterized using Fourier transform
infrared spectroscope, X-ray diffraction, scanning electron microscope,
contact angle meter, and a universal testing machine. We have observed
that while hydrochar can be incorporated with PETG to create biomass-derived
filaments, incorporating activated carbon with PETG results in superior
filaments. These composites can incorporate an extremely high biomass
filler weight percentage while enhancing mechanical strength by over
30%. Our biomass-derived PETG composites were also thermally stable
and more hydrophilic than the pure PETG samples. We analyze the mechanism
by which activated carbon incorporation increases the PETG composites’
mechanical strength with both physical and chemical techniques. We
also demonstrate successful FDM 3D printing of personalized anatomical
models and porous cylindrical filter mesh using our biomass-derived
PETG composite filaments. Implementing such sustainable principles
in the 3D printing industry has the potential to transform it into
a restorative and sustainable system while simultaneously minimizing
environmental pollution and waste.
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