Tailoring Organic–Organic Poly(vinylpyrrolidone) Microparticles and Fibers with Multiwalled Carbon Nanotubes for Reinforced Composites

Narváez‐Muñoz, Christian; Carrión-Matamoros, Luis M.; Vizuete, Karla; Debut, Alexis; Arroyo, Carlos R.; Guerrero, V.H.; Almeida‐Naranjo, Cristina E.; Morales‐Flórez, Víctor; Mowbray, D. J.; Zamora‐Ledezma, Camilo

doi:10.1021/acsanm.9b00758

Cited by 18 publications

(18 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The Raman features from PVA nor PVDF are not observed, which is consistent with the literature, because in graphitic materials, the Raman process is resonant and so its signal is much more intense than the nonresonant signal from PVA and PVDF. [31,33,34] These findings clearly indicate that the structure of the FLG flakes is conserved in the final nanocomposite. [35][36][37] 3.2.…”

Section: Raman Spectroscopymentioning

confidence: 83%

Fabrication and Characterization of Metal‐Free Composite Electrodes Based on Few‐Layer‐Graphene Nanoplatelets for Oxygen Reduction Reaction Applications

Suppan

Briones-Macías

Pazmiño-Arias

et al. 2021

Physica Status Solidi (b)

Self Cite

View full text Add to dashboard Cite

Innovative technologies such as fuel and solar cells, supercapacitors, batteries, sensors, electrochemical energy storage devices are some of the most studied solutions to future energy demands due to an exponential population increase, estimated to reach over nine billion by 2050. [1] In fuel cells, chemical energy is directly converted to electricity. This fact is the main driving force through high-performance electrodes with improved catalytic activities toward hydrogen oxidation reaction (HOR) or oxygen reduction reaction (ORR). The final performance of a microbial fuel cell (MFC) will depend on the following parameters: 1) the power at the output, 2) the current density, and 3) the Coulombic efficiency, [1,2] which in turn depend on several factors such as the conductivity and porosity of the anode, the type of proton exchange membrane used to separate the cell chambers, the type of organic substrate used in the oxidation reaction at the anode, as well as the ORR at the cathode. However, the cathodic ORR in many cases has proven to be a limiting factor in the total energy generation in the cells, hence considered as one of the greatest performance indicators of a microbial fuel cell. [2] The commercial Pt/C catalyst is the common reference because of its great performance towards ORR with a limiting current density around 6 mA cm À2 at 0.7 V versus RHE (reversible hydrogen electrode) and 1600 rpm. Catalysts such as phosphorus doped hierarchical porous carbon showed a shift of around 70 mV for the onset potential compared with the Pt/C electrode. [3] Carbon fiber paper with Pt 3 Co showing a limiting current density of 25.8 mA cm À2 at 0.2 V versus RHE and 2500 rpm [4] and nanocomposites based on hybrid Mn 3 O 4 and oxidized graphene flakes provide a limiting current density of 2.8 mA cm À2 at À0.6 V and 1600 rpm. [5,6] Despite being the material with the highest electrocatalytic activity for ORR reported so far, Pt presents certain disadvantages like its high cost, toxicity, chemical instability, and biofouling, which still limit a widespread application. [7,8] These are the principal driving forces to find affordable materials to compete with Pt for ORR. Other metals such as copper, cobalt, or iron have been also reported as good candidates to replace the expensive Pt electrodes. Those materials exhibited currents, durability, and tolerance comparable with Pt, however, their ecological impact is highly

show abstract

Section: Raman Spectroscopymentioning

confidence: 83%

Fabrication and Characterization of Metal‐Free Composite Electrodes Based on Few‐Layer‐Graphene Nanoplatelets for Oxygen Reduction Reaction Applications

Suppan

Briones-Macías

Pazmiño-Arias

et al. 2021

Physica Status Solidi (b)

Self Cite

View full text Add to dashboard Cite

show abstract

“…Electrospinning is one of the most appealing technologies for the incorporation of CDs within micro-/nanofibers and mats. This low-cost technique allows the transformation of a given viscoelastic fluid into fibrous membranes under the influence of an electric field and was observed for the first time more than a century ago [ 116 , 117 ]. The final performance of these fibrous materials is influenced by the physicochemical properties of the precursor solution, the experimental variables used during the electrospinning, and the environmental conditions.…”

Section: Methods Of Incorporating Cds In Polymer-based Active Food Packagingmentioning

confidence: 99%

Cyclodextrins in Polymer-Based Active Food Packaging: A Fresh Look at Nontoxic, Biodegradable, and Sustainable Technology Trends

et al. 2021

Self Cite

View full text Add to dashboard Cite

Using cyclodextrins (CDs) in packaging technologies helps volatile or bioactive molecules improve their solubility, to guarantee the homogeneous distribution of the complexed molecules, protecting them from volatilization, oxidation, and temperature fluctuations when they are associated with polymeric matrices. This technology is also suitable for the controlled release of active substances and allows the exploration of their association with biodegradable polymer targeting to reduce the negative environmental impacts of food packaging. Here, we present a fresh look at the current status of and future prospects regarding the different strategies used to associate cyclodextrins and their derivatives with polymeric matrices to fabricate sustainable and biodegradable active food packaging (AFP). Particular attention is paid to the materials and the fabrication technologies available to date. In addition, the use of cutting-edge strategies, including the trend of nanotechnologies in active food packaging, is emphasized. Furthermore, a critical view on the risks to human health and the associated updated legislation is provided. Some of the more representative patents and commercial products that currently use AFP are also listed. Finally, the current and future research challenges which must be addressed are discussed.

show abstract

“…Electrospinning has been used for nanofiber fabrication and modulate the nanostructure properties, namely larger surface area, small interstitial spaces, porous structure and fiber-connectivity. It was found that hydrophilicity properties of eggshell and silk nanofibers can be tuned by changing the ratio between both nanofibers in nanocomposites [ 111 , 122 ]. Modifications on the nanocomposite ratio resulted in changes in the water contact angle, which is associated with the wettability of the nanofibers [ 111 ].…”

Section: Prevention Of Covid-19 Infection Using Biomedical Sciencementioning

confidence: 99%

Biomedical Science to Tackle the COVID-19 Pandemic: Current Status and Future Perspectives

et al. 2020

Self Cite

View full text Add to dashboard Cite

The coronavirus infectious disease (COVID-19) pandemic emerged at the end of 2019, and was caused by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), which has resulted in an unprecedented health and economic crisis worldwide. One key aspect, compared to other recent pandemics, is the level of urgency, which has started a race for finding adequate answers. Solutions for efficient prevention approaches, rapid, reliable, and high throughput diagnostics, monitoring, and safe therapies are needed. Research across the world has been directed to fight against COVID-19. Biomedical science has been presented as a possible area for combating the SARS-CoV-2 virus due to the unique challenges raised by the pandemic, as reported by epidemiologists, immunologists, and medical doctors, including COVID-19’s survival, symptoms, protein surface composition, and infection mechanisms. While the current knowledge about the SARS-CoV-2 virus is still limited, various (old and new) biomedical approaches have been developed and tested. Here, we review the current status and future perspectives of biomedical science in the context of COVID-19, including nanotechnology, prevention through vaccine engineering, diagnostic, monitoring, and therapy. This review is aimed at discussing the current impact of biomedical science in healthcare for the management of COVID-19, as well as some challenges to be addressed.

show abstract

Tailoring Organic–Organic Poly(vinylpyrrolidone) Microparticles and Fibers with Multiwalled Carbon Nanotubes for Reinforced Composites

Cited by 18 publications

References 34 publications

Fabrication and Characterization of Metal‐Free Composite Electrodes Based on Few‐Layer‐Graphene Nanoplatelets for Oxygen Reduction Reaction Applications

Fabrication and Characterization of Metal‐Free Composite Electrodes Based on Few‐Layer‐Graphene Nanoplatelets for Oxygen Reduction Reaction Applications

Cyclodextrins in Polymer-Based Active Food Packaging: A Fresh Look at Nontoxic, Biodegradable, and Sustainable Technology Trends

Biomedical Science to Tackle the COVID-19 Pandemic: Current Status and Future Perspectives

Contact Info

Product

Resources

About