1. Introduction
Boron Nitride is isoelectronic to carbon and it has two major allotropes: hexagonal boron nitride (h-BN) that is similar to graphite while cubic boron nitride (c-BN) which resembles to diamond [1]. BN is produced unnaturally by boric acid or boron trioxide. Amorphous BN powder was initially produced, that is converted to crystalline like h-BN for making it the heating process is used in the presence of nitrogen flow at above 1500˚C temperature [2]. The h-BN is occasionally called white graphene because of its likeness and duality. It has got too much interest because of its infrequent electronic band arrangement and the nature of its charge carriers that results in high mobility and other incomparable quantum phenomena at room temperature. h-BN is a smart material because its structural properties were quite similar to graphite [3].
h-BN has an arrangement like honeycomb lattice. It consists of B-N rings that are covalently bonded while the hexagonal layers are bonded together by weak Vander Waals forces [4]. The interlayer space between the layers is ~0.33 nm [5]. Two dimensional h-BN nanosheets have been intensively investigated as a class of different and unique materials, due to their fascinating and advantageous properties. Boron Nitride in its Hexagonal form, is very useful for applications as lubrication, resistant coatings, high temperature and energy storing devices. It is quite challenging to obtain controlled properties and specific structures during synthesis of h-BN.
There are some methods that were used for the fabrication of hBNNs like Mechanical Exfoliation [6], Chemical Vapour Deposition [7], and Liquid Exfoliation [8]. Liquid exfoliation is the proposed method in this paper because of its feasibility and cost effectiveness [9]. While in CVD method we need a vacuum and high temperature for the yielding of hBNNs which makes it a costly method. A lot of solvents were used for the exfoliation of h-BN as like DMF, IPA, Methanesulfonic Acid [9], Ethanol and Deionized water. The mixed solvent technique was also used for the dispersion of h-BN in which water and ethanol were mixed and used as a solvent [10]. This method has many apparent advantages, such as low cost and scalability.
2. Materials and Experiment
2.1. Material
h-BN powder (purity 97%) was purchased by SANNO Tools. DMF and IPA were used as solvents for the exfoliation of h-BN. All chemicals were used as received. Si/SiO2 was used as a substrate.
2.2. Apparatus and Method
A sonicator (Great sonic, power of bath 240 W, having 50 Hz frequency) was used. First of all a beaker is taken which was cleaned by using acetone. After that by using digital mass balance 2 mg of h-BN powder was measured and mixed with 50 mL IPA in a beaker. This solution sonicated in a sonicator for 10 Hours. Similarly, another sample was also made in which 2 mg of h-BN powder is mixed with 50 mL DMF in a beaker. The solution then sonicated for the 10 hours (Figure 1).
(a) (b)
Figure 1. (a) Shows h-BN powder before Sonication while (b) shows h-BN powder after sonication.
The obtained solution was centrifuged at 3000 rpm for 10 mins. The supernatant was collected and drop cast on silicon substrate for microscopic and spectroscopic analysis (Figure 2).
Figure 2. Shows Exfoliated h-BN in DMF and IPA drop-casted on Silicon Substrate.
3. Results and Discussion
3.1. UV-Visible Spectroscopy
One can confirm the presence of h-BN with an absorption peak in the range of 210 to 280 nm [11]. As the sample exfoliated in DMF having an absorption peak at 240 nm as shown in Figure 3(a). Similarly, another sample exfoliated in IPA which shows an absorption peak that was observed at 265 nm in Figure 3(b).
Figure 3. (a) UV-Visible spectrum of multi-layers of h-BN exfoliated in DMF; (b) UV-Visible Spectrum of h-BN exfoliated in IPA.
The multilayers of h-BN exfoliated in DMF has a bandgap of 5.39 eV [4] while the multilayers of h-BN exfoliated using IPA as solvent has 4.96 eV value (Figure 4).
Figure 4. (a) Band Gap of multilayers of h-BN exfoliated in DMF; (b) Band Gap of multilayers of h-BN exfoliated in IPA.
3.2. X-Ray Diffraction
The Multilayers of h-BN were characterized under XRD to investigate the symmetry and phases. Comparative XRD patterns of h-BN multilayers exfoliated in IPA (red) and DMF (black) can be viewed in Figure 5. From the figure it reveals that diffraction peaks exhibit a slight variation of (0.21˚). As the angle obtained by exfoliated BNNSs in DMF is (27.39˚) while in IPA is (27.17˚) [12]. In contrast to both samples no extra peaks were detected in the XRD pattern of exfoliated BNNSs. The intensity obtained by exfoliated BNNSs in DMF (452) is greater than exfoliated BNNSs in IPA (203) which can be analyzed from Figure 5.
The grain size of exfoliated BNNSs in DMF is 25.62 nm while in IPA is 43.73 nm which shows that h-BN is exfoliated better in DMF with concerning to IPA. The peaks observed at angles 27˚ in both samples confirms the formation of crystallographic planes (002), which is the indication of the formation of multilayers of BNNSs [13].
Figure 5. XRD pattern of h-BN exfoliated in IPA and DMF.
3.3. Scanning Electron Microscopy
In SEM (Scanning electron microscopy) sample is scanned by using an energetic beam of electrons. Surface morphology, Chemical composition and material orientation such information is obtained by signals when beam of electron interacts with sample h-BN. In Figure 6(a), Figure 6(b) nanoflakes were pictured by SEM. These nanoflakes illustrating their plate like shape and size of the individual flake in the range of 200 nanometers which was observed in literature survey [14].
If the amount of incident electrons is higher than the amount of electrons evading from the sample, then the negative charge creates on sample at the point where the beam hits. This thing is called the charging effect [15] and it gives a range of scarce effects such as irregular contrast, image distortion and shift. That is why we see contrast in Figure 6(a), Figure 6(b) as this sample is drop cast on silicon substrate because of this we see black area where electron was distributed.
(a) (b)
Figure 6. (a) Shows exfoliated h-BN in DMF at 500 nm and (b) Shows exfoliated h-BN in IPA at 500 nm respectively.
It was observed that Nano flakes obtained by sample exfoliated in DMF have fine distribution comparing to sample exfoliated in IPA.
3.4. Dielectric Spectroscopy
The exfoliated BN powder in DMF was drop cast on silicon substrate prepared as a function of thickness. The variation of thickness was 5, 10 and 15 drops. Similarly, exfoliated BN powder in IPA also drop cast on silicon substrate as a function of thickness. The variation of thickness was 5, 10 and 15 drops. By using an LCR meter capacitance was measured through which Dielectric constant is intended [16].
The formula to calculate the dielectric constant is
In the above equation C shows capacitance, d depicts thickness, A is area of the sample and
is relative permittivity whose value is 8.85 × 10−12 [17]. Exfoliated BN powder in DMF was drop cast on silicon substrate whose thickness variation can be observed with concerning for to no of drops same is observed in sample exfoliated in IPA [18].
Dielectric Constant is measured by using the formula and it was observed that its value increases with variation in thickness irrespective of solvent as in Table 1 and Table 2.
Table 1. Shows Dielectric constant value of h-BN exfoliated in DMF varying thickness.
Table 2. Shows Dielectric constant value of h-BN exfoliated in IPA varying thickness.
In Figure 7 histogram shown that as we increase the no of drops value of dielectric constant increases.
Figure 7. Shows variation in Dielectric constant (a) exfoliated sample in IPA and (b) exfoliated sample in DMF.
4. Conclusion
Increase in the value of dielectric constant was observed by increasing the thickness of hBNNs. Multilayers of h-BN were synthesized in DMF and IPA by using chemical exfoliation method. After successful exfoliation it was deposited on silicon substrate by drop cast method for characterization. Exfoliated samples in DMF and IPA have bandgap 5.39 eV and 4.96 eV respectively that is calculated by UV Visible spectroscopy. XRD patterns of h-BN exfoliated in DMF and IPA confirmed the mono-crystallite (002) nature of h-BN. SEM confirmed the formation of h-BN nanoflakes having size of 200 nm. It was observed that nanoflakes obtained by sample exfoliated in DMF have fine distribution comparing to sample exfoliated in IPA. Capacitance is measured by using LCR meter. Using the capacitance value in a formula, the value of dielectric constant was calculated. The thickness of the samples were measured by using a profilometer. The variation was observed in value of dielectric constant as the thickness increases. h-BN nanocomposites with semi-conductor (metallic oxides) can be useful to obtain higher dielectric constant without varying thickness.