The G-mode is at about 1583 cm^-1, and is due to E2g mode at the Γ-point. G-band arises from the stretching of the C-C bond in graphitic materials, and is common to all sp² carbon systems. The G-band is highly sensitive to strain effects in sp² system, and thus can be used to probe modification on the flat surface of graphene.

The D-mode is caused by disordered structure of graphene. The presence of disorder in sp²-hybridized carbon systems results in resonance Raman spectra, and thus makes Raman spectroscopy one of the most sensitive techniques to characterize disorder in sp² carbon materials. As is shown by a comparison of (Reference) and (Reference), there is no D peak in the Raman spectra of graphene with a perfect structure.

Figure 3: Raman spectrum with a 514.5 nm excitation laser wavelengthof pristine single-layer graphene.

If there are some randomly distributed impurities or surface charges in the graphene, the G-peak can split into two peaks, G-peak (1583 cm^-1) and D’-peak (1620 cm^-1). The main reason is that the localized vibrational modes of the impurities can interact with the extended phonon modes of graphene resulting in the observed splitting.

All kinds of sp² carbon materials exhibit a strong peak in the range 2500 - 2800 cm^-1 in the Raman spectra. Combined with the G-band, this spectrum is a Raman signature of graphitic sp² materials and is called 2D-band. 2D-band is a second-order two-phonon process and exhibits a strong frequency dependence on the excitation laser energy.

What’s more, the 2D band can be used to determine the number of layer of graphene. This is mainly because in the multi-layer graphene, the shape of 2D band is pretty much different from that in the single-layer graphene. As shown in (Reference), the 2D band in the single-layer graphene is much more intense and sharper as compared to the 2D band in multi-layer graphene.

Figure 4: Raman spectrum with a 514.5 nm excitation laser wavelength of pristine single-layer and multi-layer graphene.