This invention generally relates to carbon fiber materials and dry-jet-wet-spinning of multifunctional carbon fibers.
Carbon fibers can be made from carbonized precursors, including cellulose, lignin, pitch, polyacrylonitrile (PAN), or Kevlar®. Processing parameters that can affect carbon fiber manufacturing include atmosphere effects, precursor type influences (viscose rayon fibers, PAN fibers, and isotropic pitch), and material sustainability (precursors from cellulose or lignin).
Properties exhibited by carbon fibers include physical strength, light weight, a low temperature of thermal expansion, chemical and biological inertness, high vibration damping, and high corrosion resistance. Carbon fibers have been used in the manufacture of a wide variety of products including sporting goods equipment, aerospace equipment, road and marine transport parts, medical devices, machine parts, and chemical processing equipment. Due to their mechanical and electrical properties, carbonized fibers have also been widely used in sensors, supercapacitors, actuators, electrodes, and filtration devices.
Methods for producing multilayer and multifunctional carbonized coaxial composite fibers with precise interfacial engineering for graphene morphology control are described. These methods include carbonization of polyacrylonitrile (PAN)-precursor fibers (e.g., from PAN with a molecular weight of about 230,000 g/mol) and the inclusion of graphitic layers (e.g., from graphene nanoplatelets, graphene nanoribbons, graphene nanochips, or a combination thereof). A spinning method produces a three-layered fiber that utilizes the interfacial interactions between each layer for graphene alignment between graphitic layers. In particular, a 3D printed spinneret with optimized channel structures and dimensions is employed to embed graphitic layers in PAN-based fibers. By incorporating polymers and carbon nanoparticles in separate phases, coaxial layers can be formed along the fibers. Fibers with the inclusion of 1 wt% graphene nanoplatelets (GNPs) show improved mechanical properties relative to the pure PAN fibers after carbonization. Tension-free heat-treatment is utilized during stabilization and carbonization. The resulting carbonized fibers have hybrid structures between PAN- (e.g., turbostratic) and pitch-based (e.g., graphitic) fibers, and can be used in sensors that are efficiently responsive to, for example, chemical gases and mechanical pressures. This composite containing oriented GNPs improves modulus and increases electrical conductivity for enhancing volatile organic compounds (VOCs) sensing behaviors.
In a general aspect, a carbonized coaxial composite fiber includes an inner layer including carbonized polyacrylonitrile, a middle layer surrounding the inner layer and including carbonized graphene nanomaterials, and an exterior layer surrounding the middle layer including carbonized polyacrylonitrile. The graphene nanomaterials include graphene nanoplatelets, graphene nanoribbions, graphene nanochips, or any combination thereof. The carbonized graphene nanomaterials can be aligned along a length of the coaxial composite fiber.
Implementations of the general aspect can include one or more of the following features.
In some cases, the middle layer further includes carbonized polyacrylonitrile. The middle layer can be formed from a mixture including the polyacrylonitrile and the graphene nanomaterials, and a weight ratio of the polyacrylonitrile to the graphene nanomaterials in the mixture can be in a range of 1:15 to 15:1. In some implementations, the middle layer defines voids between the carbonized graphene nanomaterials. The voids can be at least partially filled with polyacrylonitrile. In some cases, the inner layer and the outer layer include polyacrylonitrile. In some implementations, a diameter of the coaxial composite fiber is in a range of about 50 microns to about 500 microns. A diameter of the inner layer can be in a range of about 20 microns to about 80 microns. In some cases, a thickness of the middle layer is in a range of about 20 microns to about 10 microns. In some implementations, a thickness of the outer layer is in a range of about 10 microns to about 50 microns.
Forming the coaxial composite fiber of the general aspect includes forming a coagulated gel precursor fiber by extruding a multiplicity of solutions through a multiphase spinneret through an air gap and into a solvent, hot drawing the coagulated gel precursor fiber to yield a drawn precursor fiber, oxidizing the drawn precursor fiber to yield a stabilized fiber, and carbonizing the stabilized fiber to yield the coaxial composite fiber. The coagulated gel precursor fiber can include an inner layer including polyacrylonitrile, a middle layer including graphene nanomaterials, and an outer layer including polyacrylonitrile. The graphene nanomaterials can include graphene nanoplatelets, graphene nanoribbons, graphene nanochips, or any combination thereof. In some cases, the multiplicity of solutions includes a first solution, a second solution, and a third solution corresponding to the inner layer, the middle layer, and the outer layer, respectively. The first solution and the third solution can include polyacrylonitrile. In some implementations, the first solution and the third solution are the same. The second solution can include graphene nanomaterials. In some cases, the second solution further includes polyacrylonitrile. In some implementations, a weight ratio of the polyacrylonitrile to the graphene nanomaterials is in a range of 1:15 to 15:1. In some cases, the first solution, the second solution, and the third solution include dimethylformamide. The solvent can include methanol. In some implementations, hot drawing the coagulated gel precursor fiber includes heating the coagulated gel precursor fiber above the glass transition temperature of polyacrylonitrile.
The details of one or more embodiments of the subject matter of this disclosure are set forth in the accompanying drawings and the description. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
Methods for producing multilayer and multifunctional carbonized coaxial composite fibers with precise interfacial engineering for graphene morphology control are described. These methods include carbonization of polyacrylonitrile (PAN)-precursor fibers (e.g., from PAN with a molecular weight of about 230,000 g/mol) and the inclusion of graphitic layers from graphene nanomaterials (e.g., graphene nanoplatelets, graphene nanoribbons, graphene nanochips, or a combination thereof). A spinning method produces a three-layered fiber that utilizes the interfacial interactions between each layer for graphene alignment between graphitic layers. In particular, a 3D printed spinneret with optimized channel structures and dimensions is employed to embed graphitic layers in PAN-based fibers. By incorporating polymers and carbon nanoparticles in separate phases, coaxial layers can be formed along the fibers. Fibers with the inclusion of 1 wt% graphene nanoplatelets (GNP) show improved mechanical properties relative to the pure PAN fibers after carbonization. Tension-free heat-treatment is utilized during stabilization and carbonization. The resulting carbonized coaxial composite fibers have hybrid structures between PAN- (e.g., turbostratic) and pitch-based (e.g., graphitic) fibers, and can be used in sensors that are efficiently responsive to, for example, chemical gases and mechanical pressures. This composite containing oriented GNPs improves modulus and increases electrical conductivity for enhancing volatile organic compounds (VOCs) sensing behaviors.
A spinning method produces a three-layered fiber that utilizes the interfacial interactions between each layer for graphene alignment between graphitic layers. In particular, a 3D printed spinneret with optimized channel structures and dimensions is employed to embed graphitic layers in PAN-based fibers. By incorporating polymers and carbon nanoparticles in separate phases, coaxial layers can be formed along the fibers.
Oxidative stabilization is performed on the drawn precursor fiber 148 to form a stabilized fiber 150. The oxidative stabilization is performed in an oxidative atmosphere of dry air provided by dry air source 152 in a temperature range of 200° C. - 300° C., with or without applied tension F. This oxidative stabilization facilitates production of an oxidized ladder polymer parallel to the fiber axis by the cyclization of the pendant nitrile groups and the incorporation of oxygen.
Carbonization of the stabilized fiber 150 to form the carbonized coaxial composite fiber 128 is typically implemented in an atmosphere of nitrogen gas provided by nitrogen source 154 in the range of 400° C. -1500° C., with or without applied tension F. During this pyrolysis, non-carbon elements are removed as volatile products, the amounts varying with the temperature and gases evolved, which can include HCN, NH3, N2, H2O, CO2, CH4, and H2. The resulting carbon fibers typically have around 50% of the original fiber mass. End-to-end joining of cyclized regions, aromatization of non-cyclized regions, and side-by-side condensation reactions between laddered structures, which can result in broader heterocyclic regions, are observed. Dehydrogenation and denitrogenation can take place at a temperature of about 1000° C., giving rise to carbon ribbons containing limited N mass. The resulting carbon layer-plane packing can be enhanced with increased temperature treatments.
Graphitization is typically executed in an inert atmosphere above 2000° C. with applied tension for the non-graphitizing materials to be graphitized. PAN-based fibers are in the form of turbostratic graphite even after graphitization, at least because the helical crystal structure lacks a definite crystallographic arrangement of layer planes in terms of 3D stacking. Graphitization treatment, even at a high temperature of 2500° C. in argon, typically does not generate stacked graphene layers, as seen in pitch-based carbon fibers. This can also contribute to the high strength of PAN-based fibers, due at least in part to graphitic plane entanglement, while pitch-based fibers have high modulus due to close packing density and high graphitic plane orientations.
Following carbonization, the carbonized coaxial composite fiber 128 includes an inner layer 122, a middle layer 124 surrounding the inner layer 122, and an outer layer 126 surrounding the middle layer 124. The inner layer 122 includes carbonized polyacrylonitrile. The middle layer 124 includes carbonized graphene nanomaterials and can further include carbonized polyacrylonitrile. The carbonized graphene nanomaterials are aligned along a length of the coaxial composite fiber 128. The middle layer 124 can define voids between the graphene nanomaterials. The voids can be at least partially filled with PAN. The outer layer 126 includes carbonized polyacrylonitrile. The diameter of the carbonized coaxial composite fiber 128 is in a range of about 50 microns to about 80 microns. The diameter of the inner layer 122 is in a range of about 20 microns to about 80 microns. The radial thickness of the middle layer 124 is in a range of about 20 microns to about 10 microns. The radial thickness of the outer layer 126 is in a range of about 10 microns to about 50 microns.
Materials. The polyacrylonitrile (PAN) copolymer (i.e., 99.5% acrylonitrile/ 0.5% methacrylate in poly(acrylonitrile-co-methacrylic acid, with molecular weight 230,000 g/mol, and mean particle size of 50 µm, and) was obtained from Goodfellow Cambridge Limited, Huntingdon, England. Graphene nanoplatelets (GNPs) (i.e., surface area 120-150 m2/g) were obtained from Sigma-Aldrich, and carbon nanotubes (CNTs) (i.e., NC 7000, with avg. diameter 9.5 nm, avg. length 1.5 µm, avg. surface area 250-300 m2/g, carbon purity 90%, transition metal oxide < 1%, and volume resistivity measured on powder at 10-6 Ω/m) were obtained from Belgium Nanocyl SA. In thermoplastics, the percolation threshold of electrical conductivity was reported to be 0.5 wt% to 4.5 wt%. N, N-dimethylformamide (DMF) as the dispersion solvent and methanol as the coagulant were obtained from Sigma-Aldrich. All materials were purchased and used as received without further modifications.
Manufacturing processes of fiber spinning and heat-treatment. Table 1 lists the terminology for manufactured fibers and their manufacturing details. The following sections describe the preparation of the spinning procedures for three types of fibers.
# Spinnability showing a viscosity of composition 15 wt%PAN/10 wt%GNP too high to spin fibers; Y, spinnable; N, not spinnable.
+Feasibility of handing carbonized fibers during mechanical tests. Y= Yes; N= No
1-phase PAN fibers: A 15 wt% PAN/DMF solution was made by dissolving 22.5 g PAN in 150 ml DMF at 85° C. under a mechanical stir for 2 hours until obtaining a transparent solution. The solution was then deaerated in a vacuum oven (Thermo Scientific Lindberg Blue M lab oven) for 1 hour. The bubble-free solution was carefully transferred to a metal syringe connected to a syringe pump followed by fiber spinning. The injection rate was at 2 ml/min.
D-phase PAN-nanoparticle composite fibers: A dispersion of GNP/DMF was first obtained through 20 minutes of tip sonication at 60% amplitude (Q500, Fisherbrand). The dispersion was added to the prepared PAN/DMF solution to obtain different GNP concentrations (e.g., 1 and 10 wt%) followed by 2 hours of stirring at 85° C. The mixture was then transferred to a metal syringe for further fiber spinning. The injection rate was at 2 ml/min.
3-layer PAN/PAN-nanoparticle/PAN composite fibers: 3-layer fibers consisted of coaxial stacking layers. Referring to
Fiber spinning. Dry-jet wet-spinning as depicted in
Analysis. Differential Scanning Calorimetry (DSC) (DSC 250, TA Instruments Inc., USA) was conducted on 3 mg fiber samples with different heating rates to 350° C. in a nitrogen atmosphere to understand the cyclization behaviors, followed by reruns in the air for oxidation and crosslinking studies. Single filament tensile tests were conducted using a tensile tester (Discovery HR-2 hybrid rheometer, TA Instruments Inc., USA). A constant linear strain rate of 150 µm/sec and a gauge length of 5 cm was used for the pre-carbonized fibers and a constant linear strain rate of 50 µm/sec and a gauge length of 1 cm was used for carbonized fibers. For each fiber composition, the mechanical properties of 5-10 samples were tested. Scanning Electron Microscopy (SEM) was used to characterize fiber morphology, performed on a Philips XL-30 Environmental SEM (operating voltage 10 kV). All fibers were fractured in liquid nitrogen and mounted on a 90° pin stub with the fractured end facing up for SEM imaging. All SEM samples were coated with a thin gold/palladium layer (15-20 nm) for image analysis of surface morphology, voids, and interfacial interactions. Electrical resistivity measurements of the pre- and post-heat-treated fibers were tested using a multimeter (Keithley DMM 7510). The resistivity as a function of chemical gases or mechanical pressures was monitored for sensing applications.
Fiber draw ratios. After collection via fiber winding, all the PAN and composite fibers were hot-drawn to maximize the polymer chain extension. The purpose of this hot-stage drawing was to achieve better graphitic plane packing and orientations during the post-spinning (i.e., stabilization, carbonization, and graphitization) of carbon fibers. The draw ratio of pure PAN fibers was 8.0, and a 1 wt% GNP inclusion increased this value to 9.6 in the composites. The presence of 10 wt% GNP in the middle layer significantly decreased the drawability to 6.7, mainly because of the defects (e.g., voids and loose packing of GNPs). An addition of PAN in this middle layer filled these defects and increased the interaction between the middle and neighbor layers, leading to increased draw ratios of 11.6 and 8.0 for a PAN concentration of 5 wt% and 10 wt%, respectively. After heating to 150° C., the drawn fibers also showed a consistent decrease in fiber diameters, namely, 191.4 µm for 0%PAN, 114.0 µm for 5%PAN, and 65.7 µm for 10%PAN in 10%GNP, suggesting the synergistic effects of including PAN/GNP of appropriate compositions (Table 3). However, a mixture of 15 wt%PAN/DMF and 10 wt% GNP/DMF in the middle layer was not spinnable at the 2 cm air-gap due to its low viscoelastic behavior (Table 1). A combination of 15%PAN/1%GNP and 15%PAN/1%CNT was used to examine the reinforcement effects.
SEM characterization.
Kinetic analysis. Thermal stabilization plays a role in PAN-based carbon fiber fabrication, which transforms PAN polymer chains into stabilized ladder structure through oxidation, cyclization, and crosslinking reactions. As least in part because oxygen is used for the oxidation and crosslinking process, a separate monitoring strategy was used as the fibers were first run under nitrogen atmosphere to observe the cyclization process, followed by a rerun in the air to study the oxidation and crosslinking behaviors in the DSC. During these processes, different heating rates were used to monitor the kinetics and the associated activation energies. The single peak in the nitrogen atmosphere corresponds to the cyclization process (
where Ea is the activation energy (kJ/mol), φ is the heating rate (°C/min), R is the molar gas constant. Ea was taken as the slope of the plots of ln(φ/Tm2) versus 1/Tm in
The cyclization activation energies (
Mechanical analysis. The effect of increasing PAN concentration in the middle layer was analyzed with its mechanical behaviors. As shown in
To further asses the reinforcement effects from GNP alignment and exfoliations, and the assisting influences from PAN, the fibers were heat-treated first at 280° C. for stabilization and then at 1250° C. for carbonization. Afterward, PAN remained crystalline and formed a cyclized ladder polymer structure. Raman spectroscopy was performed on the HT-10%PAN/10%GNP-3 fiber to demonstrate the carbonization efficiency across the fiber with the inclusion of middle GNP containing layer. Two points in the core layer and one point in the outer shell layer were used, and their associated Raman signature peak positions and full-width-at-half-maximums (FWHM) were identical, suggesting negligible differences in carbonization efficiency across layer thickness (
After carbonization, HT-15%PAN/1%GNP-3 fiber exhibited an increase of ~76% in modulus and ~34% increase in strength compared to HT-15%PAN fiber (Table 6) with stress-strain curves shown in
Polarized Raman spectroscopy.
As one-dimensional nanoparticles, carbon nanotubes will generate different spectral features from two-dimensional graphene depending on the incident point.
Electrical properties for sensor applications. Pure PAN showed resistance beyond the testing capability of a multimeter; upon stabilization and carbonization, these fibers had a measured conductivity of 151.8 S/cm shown in
A chemoresistive sensor based on HT-15%PAN/1%GNP-3 fibers was tested. Three carbon fibers placed in parallel on a rigid substrate were put in a container and tested via an in-house designed sensing setup. A volatile organic compound (VOC) of methanol was chosen for the application as biomarker sensors. According to the Occupational Safety and Health Administration (OSHA), methanol can be harmful to humans at concentrations over 200 ppm over prolonged periods of time. Traditional solid-state VOC sensors often require a relatively high operating temperature due to their semi-conducting nature. The ability to sense these VOCs at room temperature, as the fiber sensor from this study can do, is desired to reduce the operating costs of these sensors. During the sensing tests, methanol vapors with concentrations ranging from 30 ppm, 60 ppm, 120 ppm, and 140 ppm, with a constant total flow of around 300 ml/min, were maintained at room temperature (i.e., 25° C.). Both HT-15%PAN/1%GNP-3 and HT-15%PAN fibers were tested, and their responses were calculated based on ΔR/R0 where ΔR is the resistance change and R0 is the initial resistance (
The carbonized coaxial composite fiber responds to deformation that can be caused by weight, mechanical compression, or impact encountered in structural health monitoring applications. Thus, the fibers can be used as pressure sensors.
Particular embodiments of the subject matter have been described. Other embodiments, alterations, and permutations of the described embodiments are within the scope of the following claims as will be apparent to those skilled in the art. While operations are depicted in the drawings or claims in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed (some operations may be considered optional), to achieve desirable results.
Accordingly, the previously described example embodiments do not define or constrain this disclosure. Other changes, substitutions, and alterations are also possible without departing from the spirit and scope of this disclosure.
This application claims the benefit of U.S. Pat. Application 63/285,306 filed on Dec. 2, 2021, which is incorporated herein by reference in its entirety.
This invention was made with government support under 1902172 awarded by the National Science Foundation. The government has certain rights in the invention.
Number | Date | Country | |
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63285306 | Dec 2021 | US |