3.1. Fibrillation of the Silver Nanowire
It is challenging to increase the nanowire length while using preparation procedures to manufacture silver nanowires with excellent shape. In order to obtain the ultra-long silver microfibers, we use centrifugal spinning (
Figure 1) with an annealing process using the assistance of PVP, a copolymer with a reducibility function that aids in preparing ultra-long microfibers. Centrifugal spinning facilitates the preparation of ultra-long precursors of the silver microfibers by forming an ultra-long PVP/AgNO
3 composite fiber; meanwhile, the PVP reduces Ag
+ to Ag, based on its reducibility under the annealing process.
As a synthetic water/acetonitrile-soluble polymer with an ultra-high molecular weight (PMw = 1,300,000), PVP has the general properties of facilitating water-soluble polymer colloid protection, film formation, bonding, hygroscopicity, solubilization, or condensation. It serves as the fiber’s backbone and as an Ag
+ stabilizer in the spinning solution. The spinning solution was first loaded into the rotating spinning container (
Figure 1a–c) equipped with a spinning needle for centrifugal spinning. After that, the motor starts and drives the container to rotate. When the rotating speed reaches a critical value, centrifugal force overcomes the surface tension of the spinning fluid, ejecting a liquid jet from the spinning head’s nozzle tip. The jet is then stretched and eventually deposits onto the collector, resulting in solidified nanofibers [
4]. Moreover, the PVP is commonly used to aid in the preparation of AgNW and nanoparticles because of its coordination of the Ag
+ ion with the O atom of the PVP carbonyl group [
17], which facilitates electron exchange between the Ag
+ and the adjacent N atom on the pyrrolidone ring; meanwhile, the N atoms with lone pair electrons act as electron donors, eventually reducing Ag
+ to form PVP-capped Ag [
18]. Furthermore, during the alcohol-thermal synthesis process, the molarity and molecular weight (Mw) of PVP impact AgNW production [
19]. In one PVP macromolecule, more carbonyl groups and silver ions are coordinated along the long chain of PVP. It is proposed that a higher molecular weight PVP should more easily induce the PVP-Ag coordination compound to arrange into a one-dimensional state.
In order to achieve the production of ultra-long silver microfibers, PVP was first dissolved in 5 mL of acetonitrile by vigorous stirring for 2 h at room temperature, as shown in
Figure 1d,g. The homogeneous solution was then mixed with 1 mL of distilled water, 3 g of AgNO
3, and 0.1 g of SDS, and vigorously stirred for 4 h at room temperature to produce a brown spinning solution, which was loaded into a homemade centrifuge spinning apparatus equipped with a 32 G needle. The distance between the collector (stainless steel mesh) and the spinning needle was 30 cm, while the spinning speed was 6000 rpm. Fibers with average and minimum diameters of 1.88 and 0.51 µm, respectively, were collected. The collected fiber on the stainless steel mesh was then placed into the muffle furnace, heated to 250 °C for 30 min, and held for 2 h before cooling to ambient temperature for 60 min, yielding ultra-long silver nanofibers and microfibers which have an average and minimum diameter of 1.43 and 0.31 µm, respectively.
3.2. Effect of PVP on the Morphology of the Silver Nanofiber
SEM images of the silver precursor fibers are shown in
Figure 2a–f and
Figure S1a–c. The diameter distribution of the silver precursor fiber that was generated by centrifugal spinning (
Figure 3a–c) shows significant dispersion, indicating a multi-scale structure. The diameter of the silver precursor fibers was 3–5 µm on average, and the minimum diameter of the fiber was 0.39 µm. Noticeably, the average diameter of silver precursor fibers reduces as PVP loading increases. The spinning continuity varies significantly, although fibers can be spun from spinning solutions with varying PVP:AgNO
3 ratios (4:15, 5:15, and 6:15). The weight ratio of PVP:AgNO
3 at 4:15 give the worst spinnability of spinning solution, with shorter fibers of various diameters being collected. Conversely, when the weight ratio of PVP:AgNO
3 in the spinning solution is 6:15, the spinnability is optimal, the fiber length is longer, and the fiber diameter is relatively uniform. The average length of the resulting fibers increases as the solute concentration of the spinning solution increases due to the increased co-stretching effect of the air resistance-spinning head pulling on the fibers, which results in smaller fiber diameters.
Figure 2g–i and
Figure S1d–f show the SEM image of the annealed silver fibers. It can be seen that the average diameter (
Figure 3d–f) of the obtained annealed silver fiber is between 3–4 µm, whereas the annealed silver fiber that was prepared under a PVP:AgNO
3 ratio of 6:15 has a minimum diameter (0.63 µm). Noticeably, the overall diameter of the fibers decreases after annealing because of the decomposition of PVP and SDS under high temperatures, while the average diameter of annealed silver fiber decreases as PVP content increases. According to
Figure 2 and
Figure S1, when the weight fraction of PVP in the spinning solution is up to 6:15, the fiber has a relatively complete network structure and a relatively uniform thickness.
Figure 2d–f and
Figure S2 show that the bead-string structure is suspended on the surface of the silver precursor fiber. This phenomenon is probably ascribed to the spinning jet’s extended flow converting the coiled macromolecules in the dissolved polymer into an oriented, entangled network that persists as the fiber solidifies, followed by a surface tension-driven shrinkage of the jet radius. The bead-string structure becomes less prominent as the PVP concentration increases. This is due to the higher viscosity of the spinning solution in conjunction with the decrease in surface tension. Furthermore, when comparing the SEM images of silver precursor fiber and annealed fiber prepared under various ratios of PVP:AgNO
3, the annealed fiber has a rougher surface than the silver precursor fiber, which is a result of the Ag
+ being reduced to Ag and attaching to the surface of annealed fibers during the annealing process. The morphology of the Ag particles on the different annealed fibers differed, with the Ag on the surface of annealed fiber under PVP:AgNO
3 = 4:15 having a sheet-like shape with a large aspect ratio (length from 98 to 2230 nm). Meanwhile, the Ag on the surface of annealed fiber made with PVP:AgNO
3 = 5:15 and PVP:AgNO
3 = 6:15 had a compact spherical shape with a small aspect ratio. Moreover, the Ag particles on the surface of annealed fiber prepared under PVP:AgNO
3 = 5:15 had a size of 70–2280 nm, which was larger than the Ag particles on the surface of annealed fiber prepared under PVP:AgNO
3 = 6:15 (51–766 nm).
Figure 3g depicts the X-ray diffraction (XRD) patterns of annealed silver fibers under varied PVP loading. The crystalline planes of (111), (200), (220), and (311) correspond to four typical peaks at 38.35°, 44.42°, 64.27°, and 77.40°, respectively (JCPDS file No. 04-0783) [
20,
21,
22,
23]. As a result of the low PVP loading, the samples are cubic-crystal structure metallic Ag nanoparticles attached to the fiber’s surface, with no observable diffraction peaks of 81.68°, attributable to the crystalline plane of the fiber (222). As the PVP loading increases, the peak of 81.68° becomes higher and sharper, while no diffraction peaks of Ag
2O are detected in this pattern; this indicates that PVP aids in the growth of Ag nanoparticles, and protects silver nanoparticles from oxidation [
24]. Meanwhile, the sharp and strong peaks indicate that silver nanoparticles have high crystallinity, which implies that high purity silver nanoparticles are prepared through centrifugal spinning and annealing. Based on the XRD patterns, the crystal size of the Ag nanoparticle was calculated using D = Kλ/Bcosθ, where D is the average crystallite size; K is the Scherrer constant; B is the full width at half maximum intensity of the peak; θ is the diffraction angle; and λ is the X-ray wavelength (1.54056 Å). The size of the Ag nanoparticle prepared with PVP:AgNO
3 = 5:15 was calculated to be 25.2 nm, which was larger than the size of the Ag nanoparticle prepared with PVP:AgNO
3 = 4:15 (22.9 nm) and with PVP:AgNO
3 = 6:15 (17.3 nm). The PVP aids in the preparation of Ag nanoparticles and protects them from oxidation; however, an excess of PVP loading reduces the size of the Ag nanoparticle crystal. Furthermore, the EDS image of the silver microfibers (
Figure 3h and
Figure S3) revealed that the silver nanoparticles are evenly distributed on the fibers.
3.3. Effect of Needle Size on the Morphology of the Silver Microfiber
The distribution of fiber diameters obtained with different sizes of the needles is shown in
Figure 4g–l. The average fiber diameter decreases with the needle diameter, while annealed silver fiber has a smaller diameter than silver precursor fiber. Annealed silver fibers prepared with 30 G, 32 G, and 34 G needles have diameters of 1–5, 0.4–3.5, and 0.3–1.2 µm.
Figure 4a–f,
Figures S2 and S4 show SEM images of the silver precursor fiber before and after annealing. The silver precursor fiber has high homogeneity before annealing, according to
Figures S2 and S4, and the thinner needle manufactured silver fiber has a superior shape of the bead. Moreover, the 30 G and 32 G needles can be used for continuous spinning. Conversely, the needle becomes readily blocked when utilizing a 34 G needle, lowering production efficiency dramatically. Furthermore, a 34 G needle prepares the annealed silver fiber with an average diameter of 1.23 µm, which is smaller than that of fiber prepared by 30 G (4.15 µm) and 32 G (1.88 µm) needle, illustrates that different fiber sizes can be achieved by adjusting the needle size.
The size of the needle had an effect on the development of the Ag particle on the surface of the annealed fiber, similar to the effect observed with PVP loading. However, due to the adoption of PVP:AgNO3 = 5:15, the Ag on the surface of different annealed fibers generated under different needles showed particles forming. The silver branch (480–570 nm) and aggregation powder (1.04–1.25 μm) are present on the surface of annealed fiber manufactured with a 30 G needle. Meanwhile, the Ag particles are evenly distributed on the surface of fiber produced with 32 G and 34 G needles. The reason for this is because when the diameter of the fiber increases with the size of the needle, AgNO3 aggregation in the silver precursor fiber increases.
3.4. Effect of Annealing Temperature on the Morphology of the Silver Microfiber
In order to assess the effect of annealing temperature on the formation of ultra-long silver microfibers, a precursor of silver microfibers prepared with PVP:AgNO
3 = 5:15 and a 30 G needle were annealed at 250, 280, 300, and 350 °C. As shown in
Figure 5a–h and
Figure S5, the morphology of the silver fibers annealed at different temperatures differed, as a result of the thermal properties of PVP and AgNO
3. According to the references [
17,
25], the metal ions, generally in the composite, have two distinct effects on the glass transition temperature (Tg) of polymers. Cross-linking/coordination between Ag cations and polymer electron donor groups reduces chain mobility and increases Tg. The distributed complexes in the polymer, on the other hand, reduce the crystallinity and Tg of the polymer because they disrupt the uniformity of the polymer chains. In reference [
17], the results show that the addition of Ag ions can disrupt the uniformity of PVP chains since the Tg of the initial PVP polymer decreases from 186.9 to 162.5 °C. For PVP, the second stage was 11.5% less in the temperature range of 250 to 396 °C, and the third stage was 61% less in the temperature range of 396 to 695 °C, indicating that pure PVP began to degrade above 250 °C and completely decomposed at temperatures above 695 °C. It also means that high temperature causes the PVP to decompose rapidly, releasing gas and affecting the morphology of the fiber, causing fiber fracture, as shown in
Figure 5a–h. In contrast, as the temperature rises, the size of the silver particles on the surface increases, and the connections between the silver particles form a new shell for the PVP/AgNO
3 fiber. Further more, higher Mw of PVP results in better thermal properties of PVP and a stronger fiber that resists centrifugal force and is less likely to break during the spinning process as shown in
Figure S6.
The characteristic peaks of silver (111, 200, 220, 311, and 222) were observed in the annealed PVP/AgNO
3 fiber XRD patterns, as shown in
Figure 5i. The crystalline size of the silver particle was calculated. When the annealing temperature was raised from 250 to 300 °C, the size of the silver particle increased from 25.2 to 65.9 nm. However, when the temperature was raised to 350 °C, the size of the silver particle decreased to 55 nm. Essentially, the annealing procedure at high temperatures promotes Ag crystal growth while shortening fiber lengths and destroying morphology.
3.5. Electrical Properties of the Silver Microfiber
As illustrated in
Figure S7, the pristine PVP/AgNO
3 film (weight ratio = 5:15) on the glass substrate does not have conductive properties because it lacks a conducting network constructed with conductive elements, which correspond to the Ag
+ that has not been converted into silver. The film exhibits a sheet resistivity of 500 Ω/□ after 5 min of annealing at 50 °C, illustrating the low conductive properties of the film. In other words, because some Ag
+ has been converted into silver, the annealed film possesses a conductive network. The annealing temperature and time were increased in order to convert Ag
+ into silver Ag efficiently, and the sheet resistivity of the film was as low as 567 Ω/□ after being annealed at 260 °C for 30 min, which was 10 times lower than the film that was annealed at 250 °C for 30 min. This means that increasing the annealing temperature results in reduction of Ag
+ to Ag, which yields a better conductive network. The results were consistent with the XRD patterns of centrifugally spun fibers after annealing, as illustrated in
Figure 5.
The electrical properties of silver fibers prepared with centrifugal spinning were also investigated, as shown in
Figure 6 and
Figure S8. A silver fiber bundle shows a resistance of 2.2 Ω at a length of 1 cm, while the silver fiber network shows a resistance of 4 Ω at a size of 1 × 0.5 cm, illustrating the high conductivity of the silver fiber prepared by centrifugal spinning paired with annealing (
Figure 6a,b). It was also confirmed by a bulb being lit by a 3-Volt battery when connected to a silver-fiber network in a circuit. Furthermore, the letter “X” between Z and J can still be seen after being covered by the silver-fiber network, demonstrating a certain transparency.