A wet-filtration-zipping approach for fabricating highly electroconductive and auxetic graphene/carbon nanotube hybrid buckypaper

Upscaling Thermoelectrics: Micron-Thick, Half-a-Meter-Long Carbon Nanotube Films with Monolithic Integration of p- and n-Legs

In order for organic thermoelectrics to successfully establish their own niche as energy-harvesting materials, they must reach several crucial milestones, including high performance, long-term stability, and scalability. Performance and stability are currently being actively studied, whereas demonstrations of large-scale compatibility are far more limited and for carbon nanotubes (CNTs) are still missing. The scalability challenge includes material-related economic considerations as well as the availability of fast deposition methods that produce large-scale films that simultaneously satisfy the thickness constraints required for thermoelectric modules. Here we report on true solutions of CNTs that form gels upon air exposure, which can then be dried into micron-thick films. The CNT ink can be extruded using a slot-shaped nozzle into a continuous film (more than half a meter in the present paper) and patterned into alternating n- and p-type components, which are then folded to obtain the finished thermoelectric module. Starting from a given n-type film, differentiation between the n and p components is achieved by a simple postprocessing step that involves a partial oxidation reaction and neutralization of the dopant. The presented method allows the thermoelectric legs to seamlessly interconnect along the continuous film, thus avoiding the need for metal electrodes, and, most importantly, it is compatible with large-scale printing processes. The resulting thermoelectric legs retain 80% of their power factor after 100 days in air and about 30% after 300 days. Using the proposed methodology, we fabricate two thermoelectric modules of 4 and 10 legs that can produce maximum power outputs of 1 and 2.4 μW, respectively, at a temperature difference ΔT of 46 K.

Buckypaper-Based Nanostructured Sensor for Port Wine Analysis

The development of electronic gadgets has become of great relevance for the detection of fraud in beverages such as wine, due to the addition of adulterants that bring risks to human health as well as economic impacts. Thus, the present study aims to apply a buckypaper (BP) based on functionalized multiwalled carbon nanotubes (MWCNTs)/cellulose fibers as a sensor for the analysis of Port wine intentionally adulterated with 5 vol.% and 10 vol.% distilled water and ethyl alcohol. The morphology of BP characterized by scanning electron microscopy indicates the formation of agglomerates of random MWCNTs dispersed on the surface and between the fibers of the cellulosic paper. The analysis of the response of the film through the normalized relative resistance change showed a higher response of 0.75 ± 0.16 for adulteration with 10 vol.% of water and a mean response time of 10.0 ± 3.60 s and recovery of approximately 17.2 min for adulteration with 5 vol.% alcohol. Principal component analysis (PCA) was used in data processing to evaluate the ability of BP to recognize and discriminate analytes and adulterating agents, allowing the investigation of its potential application as a low-cost and easy-to-handle multisensor.

Removal of Non-Steroidal Anti-Inflammatory Drugs from Drinking Water Sources by GO-SWCNT Buckypapers

Pharmaceutical products such as antibiotics, analgesics, steroids, and non-steroidal anti-inflammatory drugs (NSAIDs) are new emerging pollutants, often present in wastewater, potentially able to contaminate drinking water resources. Adsorption is considered the cheapest and most effective technique for the removal of pollutants from water, and, recently, membranes obtained by wet filtration method of SWCNT aqueous solutions (SWCNT buckypapers, SWCNT BPs) have been proposed as self-standing porous adsorbents. In this paper, the ability of graphene oxide/single-walled carbon nanotube composite membranes (GO-SWCNT BPs) to remove some important NSAIDs, namely Diclofenac, Ketoprofen, and Naproxen, was investigated at different pH conditions (pH 4, 6, and 8), graphene oxide amount (0, 20, 40, 60, and 75 wt.%), and initial NSAIDs concentration (1, 10, and 50 ppm). For the same experimental conditions, the adsorption capacities were found to strongly depend on the graphene oxide content. The best results were obtained for 75 wt.% graphene oxide with an adsorption capacity of 118 ± 2 mg g^-1 for Diclofenac, 116 ± 2 mg g^-1 for Ketoprofen, and 126 ± 3 mg g^-1 for Naproxen at pH 4. Overall, the reported data suggest that GO-SWCNT BPs can represent a promising tool for a cheap and fast removal of NSAIDs from drinking water resources, with easy recovery and reusability features.

GO-SWCNT Buckypapers as an Enhanced Technology for Water Decontamination from Lead

Water decontamination is an important challenge resulting from the incorrect disposal of heavy metal waste into the environment. Among the different available techniques (e.g., filtration, coagulation, precipitation, and ion-exchange), adsorption is considered the cheapest and most effective procedure for the removal of water pollutants. In the last years, several materials have been tested for the removal of heavy metals from water, including metal-organic frameworks (MOFs), single-walled carbon nanotubes (SWCNTs), and graphene oxide (GO). Nevertheless, their powder consistency, which makes the recovery and reuse after adsorption difficult, is the main drawback for these materials. More recently, SWCNT buckypapers (SWCNT BPs) have been proposed as self-standing porous membranes for filtration and adsorption processes. In this paper, the adsorption capacity and selectivity of Pb²⁺ (both from neat solutions and in the presence of other interferents) by SWCNT BPs were evaluated as a function of the increasing amount of GO used in their preparation (GO-SWCNT buckypapers). The highest adsorption capacity, 479 ± 25 mg g⁻¹, achieved for GO-SWCNT buckypapers with 75 wt.% of graphene oxide confirmed the effective application of such materials for cheap and fast water decontamination from lead.

Surface-topology-controlled mechanical characteristics of triply periodic carbon Schwarzite foams

Bulky sp²-carbon Schwarzites with negative Gaussian curvature are promising structures for practical applications due to their unique properties such as high surface area, large porosity, and stability against graphitization. Herein, a comprehensive study on the tension, compression and shear mechanical characteristics of seven triply periodic carbon Schwarzite foams with distinct topologies is performed using reactive molecular dynamics (MD) simulations. All carbon Schwarzites exhibit unique thermal and mechanical properties that are markedly dictated by the topology. One of the structures presents a negative thermal expansion coefficient. Under uniaxial tension, the temperature is able to play a positive or negative role in the tensile stiffness, and there is no apparent positive relationship between tensile strength and mass density. Subjected to compression and shear loads, carbon Schwarzites can fail due to brittle fracture, and uniform and stepwise structural instabilities. Both compression- and tension-negative Poisson's ratios are revealed to originate from a curvature-flattening deformation mechanism. Analysis of the crush force efficiency, the stroke efficiency and the energy-absorption demonstrates that carbon Schwarzites are effective energy-absorbers. This study provides a fundamental understanding of the relationship between the topology and mechanical properties of carbon Schwarzites for designing 3D graphitic nanostructures with good mechanical performances.

Exfoliated and water dispersible biocarbon nanotubes for enzymology applications

In this chapter, we report a simple and facile method to armor enzymes with carbon nanotubes (CNTs) which are exfoliated, and debundled using bovine serum albumin (BSA). The fabricated CNT/BSA dispersions are biofriendly, biocompatible, defect-free, and highly stable solutions. BSA gives maximum exfoliation efficiency, exceeding the 4mg/mL of CNT concentration compared to any previous reports. Further, the produced bioCNT dispersions were characterized by UV-visible, Raman, circular dichroism spectroscopy, and scanning electron microscopy (SEM). Exfoliation and debundling of the bioCNT dispersions is possible due to the π-π interaction, hydrogen bonding, hydrophobic interaction, and electrostatic attractive forces driving the adsorption of BSA on CNTs surface. Protein adsorption then makes a highly stable suspension in water that can be stored for a prolonged period. CNT dispersions are stable over a wide range of pH from 3 to 10 and at 4°C or 25°C for more than 2 months. Here, we also report the facile, inexpensive and green-chemistry method to fabricate a buckypaper (CNT paper), composed of the high packing density, self-assembled and randomly oriented bioCNTs, and these assemblies could be used in many emerging applications like air and water purification, nanocomposites, energy storage, and biosensing. Moreover, the CNT dispersions stabilized by BSA were successfully used in enzyme binding and kinetic studies and bound enzyme retained substantial catalytic activity. The current approach may facilitate bulk production of water dispersed CNTs in both academic and industrial laboratories. This is done by a simple method of stirring, which provides new opportunities for a wider range of CNT applications.