Introduction

In recent years carbon allotropes, such as nanodiamonds, have shown promising new applications in many fields due to its physical, chemical and surface characteristics. Their high electron mobility, field electron emission and magnetic properties1 make them important players in carbon based electronics2,3. Their tribological and mechanical1,4,5 properties give rise to harder coatings1,5, which are biocompatible and can provide improved biological prosthesis joints6 with decreased wear. This biocompatibility allied to their biosensing, optical and nanoprobing functionalities7,8 provide drug delivery and cellular labeling capacity7. This wide range of novel applications has fostered the active search for new and more efficient synthesis and production methods of carbon allotropes.

In this pursuit, it has been shown that dynamical compression is a way to steer carbon allotropes, through rapid energy variations, to phase transitions. As examples, transition from graphite to diamond headed by shock compression experiments occurs through the fast martensitic mechanism9; in a setup designed for quenching shock-compressed samples at a fast cooling rate, the n-diamond phase10 has been created and in regions of shock impacted meteorites nanodiamonds have been formed11. These observations brought to light the importance of carbon phase transformations in non-equilibrium states, spurring studies in a faster time scale using ultrashort pulses, which trigger shockwaves12,13 carrying extreme temperature and pressure in the matter. Experiments employing high peak power ultrashort laser pulses with durations around 100 femtoseconds irradiating Highly Oriented Pyrolytic Graphite (HOPG), usually under vacuum14,15,16 or in the graphite/liquid interface17, have originated sp3-bounded lattices on the graphite14,18 and provided preliminary evidences of diamond formation on the substrates14,15,16,17,19,20. Ultrashort laser shots raise promises for synthesizing known21 and still theoretically predicted22,23 sp3 carbon structures. Here, we have taken advantage of moderate energy ultrashort laser pulses to generate shockwaves and induce the formation of a diamond-like phase from the sp2 carbon polycrystalline graphite precursor.

In the present work, laser shots irradiating graphite under air dramatically modified the surface and created micrometer scale translucent structures where diamond-like crystallites were found coexisting with onion-like phases and quasi-amorphous nanometer sized graphite. Such materials were recovered after the laser irradiation process and analyzed by micro Raman spectroscopy, Scanning Electron Microscopy (SEM) and High Resolution Electron Microscopy (HREM). Considering the ultrafast optical excitation, ablation regime and the distinct laser-synthesized carbon structures, we propose an indirect mechanism in which subsequent laser-induced transformations lead to the synthesis of the diamond-like phase.

Results and Discussion

The Raman spectra and the SEM micrographs shown in Fig. 1 present the evolution of the induced modifications in the ultrashort laser pulses irradiated polycrystalline graphite sample through assessing the stages from the precursor (Fig. 1a,b), the intermediary stage found at the irradiated surface (Fig. 1c,d), to the final diamond-like structure (Fig. 1e,f).

Figure 1
figure 1

On the left are shown the Raman spectra and on the right the respective SEM images.

(a) and (b) refer to the polycrystalline graphite (precursor). (c) and (d) correspond to the laser-modified surface and in (c), the thicker red curve is the measured Raman spectrum and the gray ones are its component bands obtained from Voigt functions fittings. (e) and (f) present the measurements for the laser-created structure (the corresponding optical image is shown in the Figure S1 of the Supplementary Information, which also shows the Raman spectra for two other laser created particles). Clear morphological differences are noted between the precursor and the laser modified materials. The raw graphite contains disordered and buckled flakes (b). In (d) the material features micrometer sized globular formations composed by nanometer sized structures. Stacked layers resulting from shockwaves dynamic compressed carbon produce the structure shown in (e).

In the Fig. 1a the pristine graphite exhibits its characteristic Raman modes at 1343 and 1615 cm−1 (related to structural defects bands D1 and D2, respectively) and at 1579 cm−1 originating from the stretching of the sp2-bounded carbon atoms forming the well-known hexagonal structure (G-band)24. After irradiation, notable changes were observed in the Raman spectrum of the laser modified surface, shown in Fig. 1c, with respect to the precursor (Fig. 1a). While the D1 band appears at 1340 cm−1, the displacement of the G band to 1595 cm−1 (Fig. 1c) confirms the laser-induced pressure, since similar shifts to higher wavenumbers were verified for HOPG upon room-temperature compression25. Additionally, Raman resonances, which do not manifest in the precursor (Fig. 1a), emerge at 1087, 1245, 1425 and 1552 cm−1. Analogous spectra have been reported for an experiment that quenched Carbon Black from high-pressure high-temperature environment26 (15 GPa and 1700 °C for 15 min) and also in shocked meteorites27. In the former work, the new vibrations were declared unexplained Raman modes, while in the latter they were attributed to a new carbon phase. Considering previous works26,27,28 and our experimental observations, we suggest that these vibrations are evidence of the creation of sp3 carbon phases by the ultrafast laser excitation, as theoretical models29 have predicted sp3 lattices with rather specific Raman resonances.

The Raman spectrum of the laser-created structure transferred to a Cu grating (Fig. 1e) shows an expressively pronounced G-band at 1580 cm−1. While this band nearly dominates the spectrum, less intense vibrational resonances similar to the ones for the laser modified surface are also present. The dominance of the G-band closely resembles the Raman spectrum of HOPG26, therefore, indicating that the laser shockwaves induced reconstruction of the disordered arrangement of the pristine graphite into a more ordered graphitic phase. However, Selected Area of Diffraction (SAD) analysis of crystallites at multiple regions of this laser created structure (Fig. 1f) turned out being rather different from graphite, as can be noted in Fig. 2a (laser created particle) and 2b (polycrystalline graphite precursor). By assessing the related diffraction peaks plotted as a function of the inverse of the d-spacing (Fig. 2d), the laser induced changes are corroborated by the clear absence of the 0.338 nm interlayer distance – a signature of graphitic phase – in the created structure. Moreover, the electron diffraction pattern of this laser synthesized carbon form reasonably matches that of zinc blend diamond phase10,30 and, accordingly, lead us to argue that the laser excitation synthesized a diamond-like phase. Figure 2c exhibits a High Resolution Image corresponding to a small region of the diffraction pattern area shown in the Fig. 2a. The whole image area (16 × 16 nm2) of the Fig. 2c presents planes with 0.205 nm distance (diamond characteristic plane distance) and an amorphous background, which is also noticed in Fig. 2a.

Figure 2
figure 2

High Resolution Electron Diffraction analysis of the diamond-like phase.

SADs of the (a) laser created structures and (b) its graphite precursor; (c) HREM micrograph of the laser created structure with the characteristic 0.205 nm d-spacing of the diamond phase evidenced by the zoom of a small area shown in the bottom inset; the upper inset shows the Fourier Transform of the whole image; (d) exhibits the corresponding electron diffraction peaks as a function of the inverse of the d-spacing for the polycrystalline graphite (PG, gray spectrum) and diamond-like phase (blue spectrum).

The dark field image shown in Fig. 3b was obtained using an objective aperture to select the diffraction hales corresponding to the two more intense peaks of the diamond-like phase electron diffraction pattern (Fig. 3a). Texturized micrometer domains of the latter phase (Fig. 3b) can be observed with typical sizes around 50 × 25 nm2. In their vicinities, onion-like structures were also encountered (Fig. 3c,d).

Figure 3
figure 3

Texturized domains of the diamond-like phase and onions-like carbon coexisting at the laser created particle.

(a) SAD of the diamond-like phase from a small area on the region of the laser created structure displayed in (b). The highlighted red spot in the frame (a) represent the selected diffraction peaks for construction the patterned domains shown in (b). Onion-like phases also found at the laser created structure are presented in the frames (c) and (d).

Here we propose that the mechanism for the transformation from graphite to the diamond-like phase follows an indirect pathway that is underpinned on the morphology of the starting material, specific thermodynamical events dictated by the fluence of overlapping ultrashort laser pulses18 and the formation of natural catalysts, as the onion-like structures31 and the laser driven nanometer sized graphite26. Initially, the high densities of free electrons accumulating at the boundaries of the precursor defective graphitic flakes favored the absorption of the ultrashort pulses energy steering to the creation of superexcited states and ultimately to ablation32. As a consequence of the ultrafast excitation above the high fluence ablation threshold and the following explosive ablation, nonthermal shockwaves first propagate into the material after the electronic relaxation and then heating and thermal equilibrium take place. This thermodynamical process, which happens at each laser shot, produces cumulative incremental lattice distortions14,33 leading to more ordered carbon forms34. Considering the exposure time with pulse superposition, these latter structures behave as transient states whose energetic barrier to phase transition lowers while the crystallinity gradually increases at each shockwave shot. Therefore, the formation of the diamond-like phase is assisted by those intermediary carbon structures which assume the role of nucleation sites more prone to phase transitions35.

Conclusion

In summary, we have demonstrated, for the first time to our knowledge, the synthesis of a diamond-like phase from blasting polycrystalline graphite with spatially overlapping 25 fs ultrashort laser pulses under air atmosphere, relaxing the experimental conditions to create nanodiamonds. The diamond-like phase was found coexisting with onion-like carbon structures, in a micrometer sized translucent laser created particle that was investigated by micro Raman spectroscopy, SEM and HREM. Based on results of previous literature work and on our observations, we proposed a mechanism for the formation of the diamond-like phase from the graphite precursor. The deduced pathway of synthesis correlates the dynamics of excitation, temperature and pressure with phenomenological observations to yield relevant insights into the phase transformation of carbon allotropes by ultrafast extreme conditions.

Methods

Samples were prepared by cutting 99.99% pure polycrystalline graphite bars (Alpha Aesar) into rectangular blocks (15 × 7 × 4 mm3) whose larger surfaces were manually polished with fine sandpaper up to 10 μm (RMS) roughness. Micro Raman spectroscopy (Xplora Plus microscope from Horiba with laser excitation at 532 nm), Scanning Electron Microscopy (SEM, FEI Inspect 50F) and High Resolution Electron Microscopy (HREM, JEOL JEM 2100F) were used to characterize the precursor sample and the subsequent products of the laser irradiation. To accomplish the ablation experiments, the samples were irradiated by ultrashort pulses from a Ti:Sapphire amplified laser system (Femtopower Compact Pro HR/HP from Femtolasers). This system generated 25 fs pulses centered at 780 nm, with 558 μJ of energy, in a 4 kHz pulse train. The beam was focused in air by a 75 mm focal distance achromatic doublet and the sample was placed 1 mm before the focal plane, with the laser beam impinging on its polished face. In order to create a proper surface for the analyses, the sample was moved transversely to the beam, at 10 mm/s, in such a way to etch a line across its width; subsequently, 400 parallel lines, displaced by 10 μm, were etched and a 7 × 4 mm2 irradiated area was formed. At the sample surface, the calculated beam spot size (radius) was 67 μm, resulting in 3.96 J/cm2 fluence per pulse, which corresponds to a 1.58 × 1014 W/cm2 peak intensity. This applied fluence is three times higher than the 1.3 J/cm2 single shot high fluence ablation threshold that we measured for this material36. Moreover, we estimate that the pulses superposition were close to 300 pulses per spot, at which high fluence ablation threshold is lowered to 0.8 J/cm2,36. As a comparison, ultrashort laser pulses with fluencies as low as 60 mJ/cm2 are known to cause changes in the interplanar distance of the graphite14, a process that starts the laser ablation. After irradiation the sample was annealed (at 450 °C for 5 hours) in ambient atmosphere to eliminate debris37. Upon visual inspection of the ablated surface through the 10× magnification objective of the Raman microscope, the white illumination highlighted translucent micrometer-sized structures with different shapes, sizes ranging from 10 μm to 50 μm (Figures S1 to S3 of the Supplementary Information) and pronounced photoluminescence (Figure S2 of the Supplementary Information). Electrostatic attraction between those structures, which were found detached from the substrate probably due to the ablation process and the tip of an Atomic Force Microscope, allowed their transfer to a Cu grating for the HREM analysis.

Additional Information

How to cite this article: Maia, F. C. B. et al. Synthesis of diamond-like phase from graphite by ultrafast laser driven dynamical compression. Sci. Rep. 5, 11812; doi: 10.1038/srep11812 (2015).