Introduction

In general, the realization of artificial hydrophobic surfaces depends on the material surface chemical composition and its morphological structure. Although the chemical composition is an intrinsic material property, it can be engineered to decrease the solid surface tension1, therefore increase the hydrophobicity of the surface. On the other hand, surface roughness2,3 (micro- and nano-morphology) may also enhance the hydrophobicity, particularly by exploiting hierarchical2,4,5,6,7 and fractal architectures7,8, that allow the formation of air pockets to prevent water imbibition. Nonetheless, the fabrication of a permanent super-hydrophobic surface is a challenging task. Recently, time durability5,6,7, chemical9, mechanical10, and thermal stability11 have been addressed. Among the numerous materials having the two aforementioned features, graphene offers versatility, stability, and multi-functionality owing to its unique optical12 and electronic13 properties, making its usage widespread in hydrophobic surface realizations14,15,16.

Graphene is constituted by a sp2 lattice of graphitic carbon, thus it has a slightly hydrophilic (graphite contact angle  ≈ 86°17) but non-polar surface. Nevertheless, surface functionalization and substrate interactions may be exploited to tailor graphene wetting properties in a controlled fashion15,16. However, graphene has been used so far to realize hydrophobic coatings only employing its non-polar surface, rather than taking advantage of its surface roughness. Furthermore, graphene is not self-standing in most applications, acting thus as a coating.

On the other hand, carbon aerogels18,19,20,21,22 are carbon-based, macroscopic, three-dimensional structures characterized by a randomly crosslinking network of hierarchical nanostructures and microstructures. Typically, aerogels have high porosity, very low mass density, and large effective surface area due to their hierarchical high surface roughness, which make them a promising candidate as a super-hydrophobic material for novel technological applications. Despite a few works19,20,21,22 reporting the observation of a super-hydrophobic and lipophilic behavior in carbon aerogels, the characterization of the wetting properties of such a class of materials is still missing, to date.

Here, we give insight on the wetting properties of graphene aerogels in detail. In particular, we show that owing to their particular morphology and high surface porosity (up to 0.81), our graphene aerogels exhibit a super-lipophilic state and a stationary super-hydrophobic state, achieving high apparent contact angle values θ°≥150°, with low contact angle hysteresis1 (CAH)  ≈ 15°, and high work of adhesion (10 mJ/m2). In addition, we characterized the graphene aerogel solid surface tension (63 mN/m).

Results and Discussion

The graphene aerogels studied are made of a cellular material called Aerographene (see Methods). The samples have a square-shaped surface with a lateral size L = 2 cm, a thickness d = 0.2 cm, and a mass m = 5 − 15 mg. A representative sample is reported in Fig. 1a. From the scanning electron microscopy (SEM) micrograph in Fig. 1b, a random network made of micrometer-sized carbon tetrapods23,24,25 constituting the aerogel surface (Fig. 1b, inset) can be observed. This particular shape is due to the precursor ZnO template employed during the material synthesis. Therefore, such a highly porous (volume porosity up to  ≈ 0.99) system cannot be considered as an homogeneous solid.

Figure 1
figure 1

Aerographene aerogels morphology. (a), Image of a water droplet cast on a hydrophobic Aerographene aerogel. (b), Representative SEM micrograph of the Aerographene aerogel surface. Inset, Detail of carbon tetrapods.

The mass density of the Aerographene aerogels can be estimated at first approximation by ρ = m/V. However, this is the total mass density, as aerogels are matter with a mixed phase of gas and solid. Hence, a better estimation of the solid mass density can be provided by the effective medium approximation ρ = ρc(1 − Φ) + ρairΦ, with Φc + Φ = 1, where ρc = 2200 kg/m3 and Φc = Vc/V are respectively the density and the volume fraction of the carbon phase, while ρair = 1.225 kg/m3 and Φ = Vair/V are the density and the volume fraction of air, respectively. Hence, the effective mass density is defined as ρeff = ρc(1 − Φ). Therefore, the aerogel porous fraction is Φ = 0.992 − 0.998, leading to an effective mass density down to ρeff = 5 kg/m3.

Owing to their random surface morphology, the static contact angle on porous media can be defined only on average1. The contact angle of a water droplet cast on a representative Aerographene aerogel is shown in Fig. 2a. We measured a maximum apparent contact angle θ* = 150 ± 15° on our samples, thus the sample is super-hydrophobic (θ*≥150°). The error on the contact angle was evaluated by the CAH, that is defined as the difference between the advancing and receding contact angle (Fig. 2b). Such a low CAH is due to the highly rough and porous surface of the samples and it is peculiar of the fakir effect26.

Figure 2
figure 2

Contact angle measurements. (a), Image of a sessile water droplet cast on a super-hydrophobic (θ* = 150 ± 15°) Aerographene aerogel. (b), Contact angle as a function of time by increasing (black dots) and decreasing (red dots) the water droplet volume cast on the aerogel. The advancing and receding contact angles are marked. (c), Contact angles of Aerographene aerogel (red dots) and HOPG (black dots) as a function of the ethanol volume concentration in water. The black arrow marks the lipophilic transition point between the Wenzel and Cassie-Baxter regime. (d), Wenzel-Cassie-Baxter wetting phase diagram of the Aerographene aerogel surface with respect to the HOPG surface. Wetting states are studied changing the liquid surface tension by adding different concentrations in volume of ethanol in water. The fit of Wenzel equation (red solid line) reports a roughness factor r = 7.6 ± 0.4, while the fits of lipophilic (green solid line) and hydrophobic (blue solid line) Cassie-Baxter equations report respectively a liquid fraction Φ+ = 0.48 ± 0.03 and an air fraction Φ = 0.45 ± 0.02. The Wenzel-Cassie-Baxter transition point in the hydrophobic regime is the intersection between the red and blue solid lines, while in the lipophilic regime it is the intersection between the red and green solid lines. Error bars are standard deviations of data measured over different sample areas.

Moreover, we evaluated the work of adhesion of the aerogel surface in contact with water by the Young-Dupré equation1

$${W}_{adh}={\gamma }_{LV}(1+\cos \ {\theta }^{* }).$$
(1)

For the super-hydrophobic sample in Fig. 2a, Wadh ≈ 10 mJ/m2. Therefore, for a water drop with 1 mm diameter, the adhesion force of the Aerographene aerogel in contact with the drop is Fadh ≈ 10 μN. For instance, the obtained result is about 17% lower than the adhesion force of a single gecko foot-hair27, but 10 times higher than that of Salvinia leaf28, and compatible with the value reported for carbon nanotube films6.

In order to better understand the wettability of Aerographene aerogels, we characterized their wetting states with respect to a highly oriented pyrolytic graphite (HOPG) reference substrate (Bruker). In Fig. 2c, we report the contact angle of the super-hydrophobic aerogel and the HOPG as a function of the concentration in volume of ethanol in water. Since ethanol has a lower liquid-vapor surface tension (γLV = 22 mN/m) than water (γLV = 72 mN/m), the higher the ethanol concentration, the lower the surface tension of the overall solution.

Generally, the contact angle between a chemically homogeneous solid surface and a liquid droplet obeys to the Young relation1

$$\cos \ \theta =\frac{{\gamma }_{SV}-{\gamma }_{SL}}{{\gamma }_{LV}},$$
(2)

where γSV and γSL are the solid-vapor and solid-liquid surface tensions, respectively. Therefore, the lower the surface tension of the liquid droplet, the lower the Young contact angle of the HOPG. This phenomenon is connected to the lipophilicity of the non-polar surface of carbon-based materials. Indeed, a minimum contact angle (θ = 70°) can be measured on the HOPG for pure ethanol droplets (Fig. 2c). On the other hand, it was not possible to measure the aerogel contact angle with acetone, ethanol, and glycerol because the material instantly and completely absorbed the droplets. Hence, the Aerographene aerogels are super-lipophilic (θ* < 5°) as a consequence of their super-hydrophobic behavior. We further observed that for θ = 77°, \((\cos \ {\theta }^{* }=0.2)\) there is an intersection point between the two curves in Fig. 2c, beyond which the aerogel surface becomes more lipophilic than the graphite surface. That point corresponds to the transition point from the Wenzel to the Cassie-Baxter state in the lipophilic regime of the Wenzel-Cassie-Baxter phase diagram5, as confirmed from the plot (first quadrant) in Fig. 2d. We fit our data with the lipophilic Cassie-Baxter equation7,29

$$\cos \,{\theta }^{* }=(1-{\varphi }_{+})\cos \,\theta +{\varphi }_{+},\qquad 1=\varphi +{\varphi }_{+},$$
(3)

by considering the Aerographene aerogel as a composite surface with a solid surface fraction Φ, a surface fraction wetted by the liquid Φ+, an aerogel contact angle θ*, and a HOPG Young contact angle θ. We obtained from the fit (green solid line) a liquid fraction Φ+ = 0.48 ± 0.03 in contact with the droplet. We point out that metastable30 Cassie-Baxter states coexist with Wenzel states, which are stable as they are lower in surface free energy5. Therefore, we fit our data in Fig. 2d with the Wenzel equation3

$$\cos \ {\theta }^{* }=r\cos \ \theta ,\qquad r\ge 1,$$
(4)

where r is the roughness factor (i.e., the ratio between the actual wet surface area and its geometrical projection on the plane)5. The fit (red solid line) returned r = 7.6 ± 0.4, meaning that the Aerographene aerogel surface is quite rough (the root-mean-squared roughness is  ≈ 3 μm). In addition, from Eqs. 3 and 4 we obtain the relation

$$\cos \ \theta =\frac{{\varphi }_{+}}{r+{\varphi }_{+}-1},$$
(5)

from which we infer that the lipophilic Wenzel/Cassie-Baxter transition point occurs at \(\cos \theta =0.07\) (the intersection between the red and green solid lines in Fig. 2d), hence confirming that the achieved lipophilic Cassie-Baxter states are metastable.

On the other hand, in the hydrophobic regime (third quadrant of the plot) we observe a continuous transition between the Wenzel and the Cassie-Baxter states beyond \(\cos \ \theta =0\). Also, the plot depicts that the transition occurs by passing through metastable states extending into the fourth quadrant, slowing down the dewetting process. By fitting our data (blue solid line) in Fig. 2d with the hydrophobic Cassie-Baxter equation7,29

$$\cos \ {\theta }^{* }=\left(1-{\varphi }_{-}\right)\cos \ \theta -{\varphi }_{-},\qquad 1=\varphi +{\varphi }_{-},$$
(6)

we obtained an air surface fraction Φ = 0.45 ± 0.02 below the liquid droplet. Furthermore, from Eqs. 4 and 6 we obtain the relation

$$\cos \ \theta =\frac{{\varphi }_{-}}{1-r-{\varphi }_{-}},$$
(7)

from which we infer that the hydrophobic Wenzel/Cassie-Baxter transition point is at \(\cos \,\theta =-0.07\) (the intersection between the red and blue solid lines in Fig. 2d), thus the maximum hydrophobic Cassie-Baxter state achieved is not metastable. These results suggest an air pocket formation. Therefore, we assert that the reason of the improved hydrophobicity/lipophilicity of the Aerographene aerogel over HOPG, is the fakir effect (high contact angle and low CAH) induced by the aerogel microstructure. When the interaction of the surface with the liquid is hydrophobic, the particular surface morphology promotes the air pocket formation. Otherwise, when the interaction between the surface and the liquid is lipophilic, the morphology induces the development of a precursor liquid film1, improving the wetting behavior of the Aerographene aerogel surface. Furthermore, in composite rough surfaces, their morphology may favor a wetting transition from a Wenzel to a Cassie-Baxter state, due to air trapping5. This transition typically occurs by thermodynamically metastable states30.

In addition, we investigated the stability of the Aerographene aerogel hydrophobicity over time. Figure 3 reports the variations of the contact angle value as a function of the elapsed time since water was cast on the aerogel. In such an experiment, we show that despite the samples are porous, the contact angle is constant up to 10 min. The slight linear decrease of the droplet radius in time is only due to the liquid evaporation and not to the suction by the aerogel, otherwise the contact angle would not be constant in time along with droplet radius1,7. In addition, we demonstrated a remarkable stability over several hours of the hydrophobic Cassie-Baxter state for the Aerographene aerogel (Supplementary Material). This result is particularly relevant, as the water contact angle of other carbon-based surfaces has been reported to decrease linearly with time, from an initial value of 146° to 0 within 15 min31.

Figure 3
figure 3

Wetting stability. Stability of the contact angle in the super-hydrophobic regime over time (black dots). Normalized radius of the water droplet as a function of the elapsed time (red squares). R0 is the radius initial value.

Moreover, we estimated the solid surface tension γSV of the HOPG substrate (Fig. 4a) and the graphene aerogel (Fig. 4b) by the Neumann equation17

$${\rm{\log }}\left[{\gamma }_{LV}{\left(\frac{1+\cos {\theta }^{* }}{2}\right)}^{2}\right]={\rm{\log }}\left({\gamma }_{SV}\right)-\beta {\left({\gamma }_{LV}-{\gamma }_{SV}\right)}^{2},$$
(8)

where γLV is the liquid-vapor surface tension of the different concentrations in volume of ethanol in water and β is a constant. The fit in the lipophilic regime returns γSV ≈ 42 mN/m and γSV ≈ 63 mN/m for the HOPG and the graphene aerogel, respectively.

Figure 4
figure 4

Solid surface tension characterization. Neumann equation in the lipophilic regime as a function of the liquid-vapor surface tension of different concentrations in volume of ethanol in water for the HOPG substrate (a) and the graphene aerogel (b). Red solid curves are quadratic polynomial fits.

In summary, we investigated the wetting properties of graphene aerogels. We demonstrated that such a material can be in a super-lipophilic, thus super-hydrophobic state that is stationary. The evaluated adhesion force of the water droplets with the aerogel is higher than the leaves of aquatic plants and we estimated the graphene aerogel solid surface tension. Stationary super-hydrophobic behavior of solid surfaces is a relevant property in a number of natural2 and technological processes32 with several industrial applications such as waterproof surfaces33, anti-sticking34, anti-contamination4, self-cleaning32, anti-fouling35, anti-fogging36, low-friction coatings10, adsorption37, lubrication17, dispersion1, self-assembly5, and optoelectronic and fluidic devices38,39.

Methods

Fabrication of the aerographene aerogels

A macroscopic (2 × 2 × 0.5 cm) and highly porous ( ≈ 0.94) template consisting of interconnected ceramic ZnO tetrapods23,24,25 was infiltrated with an aqueous dispersion (2 mg/ml) of electrochemically exfoliated graphene flakes40. After evaporation of the solvent and self-assembly of the graphene flakes on the template surface, the ZnO template was removed by chemical etching in 1 M HCl and subsequent critical point drying resulted in a macroscopic, free-standing random network of hollow, interconnected carbon tetrapods having a wall thickness on the order of a few nanometers, length  ≈ 20 μm, and diameter about a few micrometers.

Contact angle measurements

Images of sessile water drops deposited on Aerographene aerogels were acquired by Dataphysics OCA instrument and analyzed by its software. In order to estimate the average, maximum, and minimum contact angle on the aerogel surface, static, advancing, and receding contact angles1 were measured, respectively, by increasing and decreasing the volume of the drop by 1 μL steps. In static contact angle measurements, the volume of the deionized (18.2 MΩcm) water droplet was V = 15 μL. Every contact angle was measured 15 s after drop casting to ensure that the droplet had reached its equilibrium position, and it was averaged over the values obtained in different areas of the sample surface. Due to the heterogeneous and porous aerogel surface, we evaluated the error on the contact angle values by CAH ≈ 15°. The experimental contact angle probably corresponds to a lower limit, as the water droplet might cause some small dimple on the aerogel surface. The calculated surface air and liquid fractions are effective values, as they were determined by macroscopic techniques relying on the surface properties of the material. The liquid-vapor surface tension of the concentrations in volume of ethanol in water was measured by the pendant drop method1.