Observation of strain effect on the suspended graphene by polarized Raman spectroscopy

Abstract

We report the strain effect of suspended graphene prepared by micromechanical method. Under a fixed measurement orientation of scattered light, the position of the 2D peaks changes with incident polarization directions. This phenomenon is explained by a proposed mode in which the peak is effectively contributed by an unstrained and two uniaxial-strained sub-areas. The two axes are tensile strain. Compared to the unstrained sub-mode frequency of 2,672 cm⁻¹, the tension causes a red shift. The 2D peak variation originates in that the three effective sub-modes correlate with the light polarization through different relations. We develop a method to quantitatively analyze the positions, intensities, and polarization dependences of the three sub-peaks. The analysis reflects the local strain, which changes with detected area of the graphene film. The measurement can be extended to detect the strain distribution of the film and, thus, is a promising technology on graphene characterization.

Background

Raman and surface-enhanced Raman spectroscopy have been widely used to investigate vibration properties of materials[1–6]. Recently, they have been used as powerful technologies to characterize the phonons of graphene[7–14]. With its one to several atomic layers, graphene is the thinnest sp² allotrope of carbon, and therefore holds many unique electrical and optical properties, interesting scientists and technologists[15–19]. The unique properties change with the number of atomic layers, defects, and dopants. These factors also affect graphene's phonon modes, and therefore, Raman spectroscopy is a useful method to reflect the variation of the properties[20–22]. In addition, Raman spectroscopy can be employed to determine strain, which modifies the characteristic of materials, such as band structure, and thus influences the performance of corresponding devices[23–25]. Recently, several groups study strain of graphene by artificially bending or stretching the film and then measuring the corresponding Raman spectra[26–30].

Methods

Suspended graphene are fabricated by mechanical exfoliation of graphene flakes onto the oxidized silicon wafer. First, ordered squares with areas of 6 μm² are defined by photolithography on an oxidized silicon wafer with oxide thickness of 300 nm. Reactive ion etching is then used to etch the squares to a depth of 150 nm. Micromechanical cleavage of HOPG with scotch tape is then used to deposit the suspended graphene flakes over the indents, as shown in the schematic of Figure1a. Optical micrograph and atomic force microscopy (AFM) image, as shown in Figure1b,c, were used to characterize the suspended graphene. The surface of suspended graphene was bulging as indicated by AFM cross-section. The strain and defects of graphene are usually measured by Raman spectroscopy. To understand the strain of the suspended graphene, a micro-Raman microscope was used to perform Raman polarization-dependence measurements. A 532-nm frequency-doubling Nd-YAG laser serves as the excitation light source. The polarization and power of the incident light were adjusted by a half-wave plate and a polarizer. The laser power was monitored by a power meter and maintained through these measurements. The excitation laser power measured by the power meter is 8 mW. The laser power is measured on the delivered path between the polarizer and spectroscopy. After the delivery of laser light, the power of laser on the graphene surface is finally about 0.45 mW. The laser beam was focused by a ×50 objective lens (NA = 0.75) to the sample with a focal spot size of approximately 0.5 μm, representing the spatial resolution of the Raman system. The scattered radiation was collected backward with the same objective lens and polarization-selected by a polarization analyzer. Finally, the radiation was sent to a 55-cm spectrometer plus a liquid-nitrogen-cooled charge-coupled device for spectral recording. For the polarization dependent measurement, the polarization of incident (scattered) laser is controlled by the polarizer (analyzer). In the exploration, the polarization direction of the incident and scattered light are variable and fixed, respectively. The variability of polarization direction of the scattered light is 20°.

Figure 1

Images of the suspended graphene. (a) The scheme, (b) optical image, and (c) AFM image of the suspended graphene. The AFM image included the topography and its cross-section.

Results and discussion

Polarized Raman spectra of 2D modes under incident lights with different polarization angle (Φ) are shown in Figure2. The Φ is defined as the included angle between the incident polarization direction and the analyzer. The clear anti-symmetric spectra with different polarization angle can be observed in the spectra. Fitting of the 2D peaks is done using a double-Lorentzian function for Φ of (a) 0° and (b) 90°.

Figure 2

Polarized Raman spectra of 2D modes under incident lights with different polarization angle ( Φ ). The Φ is defined as the included angle between the incident polarization direction and the analyzer.

The 2D peak originates from four-step Stokes-Stokes double-resonance Raman scattering[31]. According to the previous review, the 2D band split when strain is applied[32]. The two angles relating to the two maximum peak positions are exhibited in Figure3, respectively. The two Lorentzian peaks for Figure3a are at 2,646 (2D₋) and 2,660 (2D₊) cm⁻¹, while that for Figure3b are at 2,647 (2D₋) and 2,662 (2D₊) cm⁻¹. To systematically analyze the sub-peak of the 2D modes, the spectra of 2D modes with different polarization angle can be fitted by double-Lorentz function, and the 2,647 and 2,660 cm⁻¹ by average of all the peak positions of 2D₊ and 2D₋ modes with different polarization angles. The 2D₀ showed the peak position at 2,672 cm⁻¹ as an original 2D peak in the unstrained graphene. The peak positions of 2D₊ and 2D₋ modes compared with an original 2D peak both red shifts. The results showed that the 2D₊ and 2D₋ modes are both tensile strains on suspended graphene. To understand the strain effect of the suspended graphene, fitting the 2D peak of graphene by a triple-Lorentzian function whose three peaks correspond to the sub-modes of 2D₊, 2D₋, and 2D₀ with Φ = 40°, which is just an example of all the spectra, is shown in Figure3c.

Figure 3

Fitting the 2D peaks with a double-Lorentzian function. Φ of (a) 0° and (b) 90°. The two angles relate to the two maximum peak positions in Figure2, respectively. The two Lorentz peaks for (a) are at 2,646 (2D₋) and 2,660 (2D₊) cm⁻¹, while that for (b) are at 2,647 (2D₋) and 2,662 (2D₊) cm⁻¹. (c) For Φ of 40°, fitting the 2D peak of graphene by a triple-Lorentzian function whose three peaks correspond to the sub-modes of 2D₊, 2D₋, and 2D₀. The green curves represent the fitting peaks for the corresponding spectra. The black curves display the spectra, while the red ones show the profiles by adding all the related fitting peaks.

To systematically analyze the intensities of the fitting sub-peaks, the plots of I(2D₊), I(2D₋), and I(2D₀) as functions of Φ is shown in Figure4. The analysis of the suspended graphene was shown in Figure4a. The 2D₊ and 2D₋ sub-bands which have the peak positions of 2,647 and 2,660 cm⁻¹, respectively, showed a prominent sinusoidal intensity modulation with a period of 180°. Both the modulation of the 2D₊ and 2D₋ bands can be fitted by a function of cos²(θ_A − θ_P), where θ_A and θ_P are the polarization angles of the analyzer and polarizer, respectively. Both the intensities of 2D₊ and 2D₋ modes are the maximum when Φ = 0° and minimum when Φ = 90°. This result of suspended graphene is very different from those of the supported graphene by previous research[32]. Compared with supported graphene, the same direction of tensile strain on the suspended graphene by analyzing 2D₊ and 2D₋ modes can be obtained.

Figure 4

Analysis of intensity. (a) Suspended and (b) supported graphenes. The plots of I(2D₊), I(2D₋), and I(2D₀) as functions of Φ. The symbol ‘I’ denotes the intensity of the corresponding sub-peak obtained by fitting the related Raman spectrum with a triple-Lorentzian function. The obtained intensities are shown by the dots, which are fitted by the form of A cos²(Φ − Φ₀) for I(2D₊) and I(2D₋), and of a constant of A, where A and Φ₀ are fitting parameters. The black and red lines display the fitting results.

The strains of the 2D₊ and 2D₋ can be calculated by employing the Grüneisen parameter[27] (γ) for the 2D mode of graphene. The corresponding equation is written as$\omega ={\omega }_0\gamma \left({\epsilon }_{\mathit{\text{xx}}}+{\epsilon }_{\mathit{\text{yy}}}\right)$, where ω₀ is the 2D peak position at zero strain and Δω is the shift caused by the strain of ε. For the uniaxial strain,${\epsilon }_{\mathit{\text{xx}}}$is the uniaxial strain and${\epsilon }_{\mathit{\text{yy}}}=-0.186{\epsilon }_{\mathit{\text{xx}}}$ is the relative strain in the perpendicular direction due to Poissons’ ratio of graphene[33]. In addition, the γ has been measured as 1.24 from the experiment on CNTs[34]. Hence the stains of${\epsilon }_{\mathit{\text{xx}}}$ for the 2D₊ and 2D₋ are estimated as 0.44% and 0.93%, respectively. Based on these results, the distribution of strain on the suspended graphene can be obtained through our analysis.

Another interesting phenomenon measured from our sample can be observed in Figure4b. The analysis of the supported graphene which was used the same method in Figure4a was shown in Figure4b. The 2D₊ and 2D₋ sub-bands having the peak positions of 2,651 and 2,661 cm⁻¹, respectively, showed a prominent sinusoidal intensity modulation with a period of 180°. Both the modulation of the 2D₊ and 2D₋ bands can be fitted by a function of cos²(θ_A − θ_P), where θ_A and θ_P are the polarization angles of the analyzer and polarizer, respectively. Both the intensities of 2D₊ and 2D₋ modes are the maximum when Φ = 1° and minimum when Φ = 91°. Using the same calculation, the stains of${\epsilon }_{\mathit{\text{xx}}}$ for the 2D₊ and 2D₋ are estimated as 0.44% and 0.93%, respectively. The result in Figure4b is similar with Figure4a. Based on the results, we believed the strain will be relaxed to a new condition during the fabricated process of substrate.

Conclusion

We have explored the suspended graphene by polarized Raman spectroscopy. In the exploration, the polarization direction of the incident and scattered light are variable and fixed, respectively. The position and intensity of the graphene's 2D peak is modified by the incident polarization, and the modification is explained by a proposed biaxial-strained model. In this model, the 2D peak is contributed by three effective areas related to unstrained and two tensile-strained graphene, respectively. The two strains are uniaxial and in the same directions. The strength of the strains is quantified through our analysis. This analytical method can be used to probe strain and help us understand the situation of suspended graphene. Hence, this method provides great application potential on graphene-based electrical and optical devices, whose performance usually relies on strain.