Water-Dispersed High-Quality Graphene: A Green Solution for

Aug 6, 2019 - The MSC device also allows ultrahigh speed operations up to 1000 V s–1, being .... (f, g) HR-TEM images of EG; the squared box area in...
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Water-Dispersed High-Quality Graphene: A Green Solution for Efficient Energy Storage Applications Zhaoyang LIU, Heng Zhang, Matilde Eredia, Haixin Qiu, Walid Baaziz, Ovidiu Ersen, Artur Ciesielski, Mischa Bonn, Hai I. Wang, and Paolo Samorì ACS Nano, Just Accepted Manuscript • DOI: 10.1021/acsnano.9b04232 • Publication Date (Web): 06 Aug 2019 Downloaded from pubs.acs.org on August 6, 2019

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is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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Water-Dispersed High-Quality Graphene: A Green Solution for Efficient Energy Storage Applications Zhaoyang Liu, † Heng Zhang, ‡ Matilde Eredia, † Haixin Qiu, † Walid Baaziz, § Ovidiu Ersen, § Artur Ciesielski, †* Mischa Bonn, ‡ Hai I. Wang, ‡ Paolo Samorì†* †

Université de Strasbourg and CNRS, ISIS, 8 allée Gaspard Monge, 67000 Strasbourg, France. ‡

Max Planck Institute for Polymer Research, Ackermannweg 10, 55128 Mainz, Germany §

Institut de Physique et Chimie des Matériaux de Strasbourg (IPCMS), UMR 7504 Université de Strasbourg and CNRS, 23 rue du Loess, 67034 Strasbourg, France *corresponding authors: [email protected]; [email protected] KEYWORDS: solution-processable, water-dispersed graphene, high-quality, electrochemical exfoliation, micro-supercapacitors

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ABSTRACT

Graphene has been the subject of widespread research during the last decade because of its outstanding physical properties which make it an ideal nanoscale material to investigate fundamental properties. Such characteristics promote graphene as a functional material for the emergence of disruptive technologies. Yet, to impact our daily-life products and devices, high-quality graphene needs to be produced in large quantities, using an environmentally-friendly protocol. In this context, the production of graphene which preserves its outstanding electronic properties using a green chemistry approach remains a key challenge. Herein, we report the efficient production

of

electrode

material

for

micro-supercapacitors

obtained

by

functionalization of water-dispersed high-quality graphene nanosheets with polydopamine. High-frequency (terahertz) conductivity measurements of the graphene nanosheets reveal high charge carrier mobility up to 1000 cm-2 V-1 s-1. The fine water dispersibility enables versatile functionalization of graphene, as demonstrated by the pseudocapacitive polydopamine coating of graphene nanosheets. The polydopamine functionalization causes a modest, i.e. 20%, reduction of charge carrier mobility. Thin film electrodes based on such hybrid materials for micro-supercapacitors exhibit excellent electrochemical performance, namely high volumetric capacitance of 340 F cm-3 and power density of 1000 W cm-3, thus outperforming most of the reported graphene-based micro-supercapacitors. These results highlight the potential for water-dispersed, high-quality graphene nanosheets as a platform material for energy storage applications. 2 ACS Paragon Plus Environment

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To address the ever-increasing energy demands in diverse technologies to improve the quality of our lives, the development of reliable and Eco-friendly approaches for energy storage systems (ESSs) has become one of the major challenges for the society.1 In particular, the next generation of wearable electronics will require the use of light-weight, flexible, and highly-conductive materials. Graphene, which is the ancestor of the growing family of two-dimensional atomic crystals, is being regarded as a rising star material for ESSs, because it combines very high mechanical robustness, excellent electrical and thermal conductivity, large specific surface area, and high intrinsic areal capacitance.2 Among current ESSs, micro-supercapacitors (MSCs) with planar architectures have recently emerged as potential energy source for future generation of on-chip miniaturized electronics in a flexible or even wearable form, since they are capable of sustaining high power, fast charging/discharging and long cycling lives, without the safety concerns as for batteries.3,4 In recent years, different strategies have been pursued to achieve interdigitated electrode arrays utilizing graphene or graphene-based hybrid materials. These attempts have been based primarily on employing graphene oxide (GO) as a precursor for fabricating graphene-based MSCs.5-12 This trend can be explained by the fact that GO, rather than graphene itself, can be produced via low-cost and scalable wet-chemical approaches,13 and perhaps even more importantly, once produced, GO can be subsequently functionalized to combine pseudocapacitive materials such as metal oxide nanoparticles or conducting polymers.14-19 Advanced techniques to 3 ACS Paragon Plus Environment

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subsequently convert GO into graphene, include laser scribing, which directly converts GO into graphene,8, 10, 20 selective electrophoretic deposition of GO followed by chemical reduction,5 and methane plasma treatments which can partially repair the defects of GO.9 However, reduced graphene oxide (RGO) constitutes moderate-quality graphene, given the presence of abundant defects (at both edges and surfaces of RGO nanosheets). As a result, RGO does not exhibit graphene's exceptional electronic properties, which cannot indeed be fully restored even after (electro)chemical/thermal reduction. Moreover, the re-stacking of RGO in water is another fatal drawback, which can cause a severe decrease of the electrochemically accessible surface area, which limits the overall performance of graphene-based MSCs. Therefore, the production of solution-processable high-quality graphene nanosheets via a scalable approach is highly desirable.21 Recent studies in electrochemical exfoliation of graphite highlight the potential of such a method as an efficient wet chemical approach to produce high-quality graphene in large quantities.22 Due to the fast exfoliation process, only minor oxidation occurs at the graphite electrode. Notably, the absence of functional groups on the obtained electrochemically exfoliated graphene (EG) surface makes them only dispersible in high boiling point and often highly toxic organic solvents such as N-methyl-2-pyrrolidone (NMP) or N, N-dimethylformamide (DMF). This issue limits the subsequent processing and functionalization of EG, and the use of toxic organic solvents may raise both

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environmental and health concerns. Thus, the fabrication of high-quality graphene via environmentally friendly approaches is highly desirable. Herein, we report the efficient production of electrode material for micro-supercapacitors obtained by functionalization of water-dispersed high-quality graphene nanosheets with polydopamine (PDA). The graphene nanosheets obtained via efficient and fast electrochemical approach reveal a low oxygen content of 12 atom % as determined by X-ray Photoelectron Spectroscopy (XPS), a low ratio between 2D band and G band as evidenced by Raman spectroscopy, a high electrical conductivity of 340 S cm-1 as measured by a four-probe system, and a high charge carrier mobility up to 1000 cm-2V-1s-1 as quantified by Terahertz measurements. Such characteristics provide unambiguous evidence for the preserved high-quality nature of obtained EG nanosheets. Morphology studies by atomic force microscopy (AFM) and high-resolution transmission electron microscopy (HR-TEM) indicate that the obtained EG are dominated by bi-layer flakes. In order to boost the overall MSC device performance, the as-produced EG nanosheets were further functionalized by pseudocapacitive polydopamine (PDA). After PDA functionalization, the intrinsic electrical transport properties of EG studied by THz spectroscopy are found to be well preserved (with only a minor decrease of conductivity of ~ 20%). PDA-EG based electrodes for MSCs exhibited high performance, with a volumetric capacitance of 340 F cm-3 and a high-power density of 1000 W cm-3, which outperformed most of the reported values of graphene-based MSCs. The MSC device also allows ultrahigh

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speed operations up to 1000 V s−1, being three orders of magnitude higher than conventional sandwich-structured electric double-layer capacitors. RESULTS/DISCUSSION Figure 1 illustrates the general procedure employed towards water-dispersed electrochemically exfoliated graphene (EG) nanosheets. A cryogenic pretreatment was first applied to graphite foil, by soaking it alternatively in liquid nitrogen and absolute ethanol (Figure 1a), during which, both the violent nitrogen evolution and the ethanol solidification process weakens the interlayer van der Waals interactions between the graphene layers and result in the volume expansion by nearly 10 times. Meanwhile, a large number of small cracks are formed at the graphite intralayer grain boundaries, due to the drastic volume change. The volume expansion, as well as the generated cracks, provides certain pathways for capillary effects, which facilitate the subsequent intercalation of anions within the graphite layers during electrochemical exfoliation.23-25 The electrochemical exfoliation of graphite was conducted by a custom-made two electrode system, where graphite foil was acting as anode and platinum foil was acting as a cathode (Figure 1b), driven by direct current voltage (10 V). An aqueous solution of 0.1 M NaOH was employed as an electrolyte, which is capable of exfoliating graphite into graphene after a long period (2h), as witnessed by the gradual darkening of the solution. After washing and mild sonication, the obtained graphene can be finely dispersed in water. Typically, a slow electrochemical exfoliation is attributed to the insufficient anion intercalation within the graphite 6 ACS Paragon Plus Environment

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layers, and in general, the obtained material exhibits increased levels of oxygen. To improve the exfoliation process and obtain graphene nanosheets with lower oxygen content, we propose a mixed electrolyte approach, as shown in Figure 1b. Although the overall mechanism for electrochemical exfoliation of graphite is not fully unraveled, sulfate anions are commonly suggested to be efficient for graphite intercalation under certain bias.26,27 Here, we propose an efficient approach, in which small amount of sulfate anions is used to intercalate graphite foil and thus makes easier access for hydroxyl anions, which subsequently exfoliate the material and ultimately graphene nanosheets are obtained. An aqueous solution of 0.1 M Na2SO4 was thus mixed with NaOH and the ratio was carefully controlled to optimize the quality of exfoliated material. The optimal ratio between NaOH and Na2SO4 was determined to be 10:1, which allows the complete exfoliation of graphite foil (thickness around 1.3 mm after pretreatment) within 30 minutes. When the Na2SO4 content is increased to, for example, 5:1, the exfoliation process is accelerated and finishes within 12 minutes. However, the obtained EG cannot be well dispersed in water due to insufficient oxygen content. On the other hand, when the amount of Na2SO4 is reduced to, for example, 25:1, the exfoliation is slowed down and takes 1 hour. Moreover, when NaOH alone is employed as an electrolyte, the exfoliation duration was found to exceed 3 hours. Figure 1c shows the photograph of a stable water dispersion of the as produced EG ink. In order to confirm the colloidal nature of the dispersion, we performed the Tyndall effect and salt effect, as well as the Zeta potential measurements, which are 7 ACS Paragon Plus Environment

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typically conducted for colloidal dispersions. As shown in Figure 1d, a diluted EG dispersion exhibits significant Tyndall effect, where a laser beam leaves a clear distinguishable light track due to scattering. Adding salt (NaCl solution) to the EG water dispersion leads to fast aggregations of EG flakes (Figure 1e). The concentration of the sodium chloride solution is 5 M in water. Upon addition of the salt solution drop-wisely, the severe aggregation of EG flakes takes place in 5 minutes. The obtained Zeta potential values based on these three conditions are all lower than -35 mV (Fig. S1 in the Supporting Information), suggesting sufficient electrostatic repulsion which explains the high stability of the EG aqueous dispersion.28 Such strong electrostatic repulsions can be attributed to the ionization of the oxygen-containing groups on EG surface, which is studied by X-ray photoelectron spectroscopy (XPS) as shown in Figure 2a. Similarly to the case of graphene oxide (GO) with well-known bonds composition, the EG surface exhibits minor oxidized species, i.e., carboxylic and hydroxyl groups, introduced during the electrochemical exfoliation process. The appeared four peaks can be attributed to the various oxygen containing groups, i.e., C-OH (centered at 284.9 eV), C-O-C (centered at 285.9 eV), C=O (centered at 287.2 eV) and C-OOH (centered at 290 eV). Additionally, the peak centered at 284 eV is attributed to C=C/C-C bond. However, the total oxygen content of EG is only 12%, being comparatively lower than that of GO and thermally reduced graphene oxide (TRGO), which exhibit an oxygen content of 31% and 14%, respectively (Fig. S2 and S3a). Here the comparison of oxygen content is confined to 8 ACS Paragon Plus Environment

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water-dispersible derivatives of graphene, rather than EG obtained via fast electrochemical exfoliation exhibiting lower oxygen content, which can only be dispersed in high-boiling point organic solvents. This comparison suggests that the obtained water-dispersed EG should exhibit largely preserved electronic properties, which, based on the oxygen content, are expected to outperform TRGO. Moreover, the thermal reduction treatment of our EG (500°C under vacuum) removes the hydroxyl groups significantly and results in very low oxygen content of only 4.8%, being even lower than the theoretical limit for RGO after 1500 K annealing.29,30 Such direct comparison suggests the enormous potential of our water-dispersible EG in replacing RGO as solution-processed high-quality graphene for future perspectives. Raman spectroscopy is subsequently employed to identify the quality of EG further, as shown in Figure 2b. A dispersion containing EG nanosheets is drop-cast on SiO2/Si substrate. The narrow G band at 1584 cm-1 corresponds to the first-order scattering of the E2g vibrations of the graphene lattice. An intense and symmetric 2D band at around 2710 cm-1 suggests the nature of few-layer graphene (2−4 layers), which could be due to the reaggregation during sample preparation. The asymmetric 2D band of graphite is shown in Fig. S3b. Surprisingly, the intensity ratio between the 2D and G bands (I2D/IG) amounts to 0.7, being comparable to that of microwave reduced GO, and is larger than chemically/thermally reduced GO, liquid phase exfoliated graphene, and HOPG, indicating the high quality of our EG.29 Meanwhile, a pronounced D band at 1354 cm-1 is observed, which can be ascribed to the presence of defects, such as edges and unavoidable oxidation during the deliberately prolonged electrochemical 9 ACS Paragon Plus Environment

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exfoliation process. The intensity ratio between D band and G band (ID/IG) amounts to 1.3, being comparable to the typically reported electrochemical exfoliation with sulfuric acid as electrolyte,31 and even smaller than some salt-based electrolyte case and TRGO.32-34 The results of the statistical analysis of EG thickness distribution carried out by AFM are portrayed in Figure 2c and d, Fig. S4. It reveals a predominance of sheets exhibiting a thickness of 1.60 nm, concluded to be bilayer graphene in accordance with the thickness of freshly cleaved single-layer graphene measured on SiO2 substrates (0.6-0.8 nm).35 A cross-sectional analysis of 60 EG nanosheets suggests that most of the obtained EG flakes are thinner than 3 nm, among which about 60% of the sampled graphene sheets has a thickness between 1 and 2 nm. Thus, our obtained EG nanosheets are mainly composed of bilayer graphene. Transmission electron microscopy (TEM) revealed certain overlapping between the EG nanosheets (Figure 2e and S5), which originates from the drying process during sample preparation. The high-resolution TEM further confirmed the bilayer nature of EG (Figure 2f and g). The selected-area electron diffraction (SAED) pattern of EG exhibits a typical 6-fold symmetry (Figure 2h), characterized by stronger diffraction from the (1-210) diffraction spot than (0-110), demonstrating the high crystallinity nature of bilayer graphene. Scanning electron microscopy (SEM) reveals the prevalent lateral-size of EG nanosheets is 2-4 μm (Figure 2i). The electrical conductivity measurement shows a significant conductivity of 340 S cm-1 based on EG films (Fig. S7), suggesting the preserved electronic properties. 10 ACS Paragon Plus Environment

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The fine dispersibility and preserved properties make our EG a promising material for energy storage-related devices, especially to fabricate MSCs based on graphene inks. Highly concentrated EG dispersions (10 mg mL-1 in isopropanol) can be employed as printable inks to achieve large area in-plane MSCs on paper substrates, by spray-coating through a shadow mask (Fig. S8a). The printed patterns of EG shows a significant low resistance of 7 Ω -1 (~3 μm thick film), which is superior to that of state-of-the-art carbon nanotube-based conductive papers (10 Ω -1 based on several μm thick film).36 The low resistance of EG patterns makes the use of metal (typically gold) current collectors unnecessary, which simultaneously reduces the cost of the device and demonstrates the possibility of future scalable production of flexible/wearable MSCs arrays based on EG. However, being only capable of electrical-double-layer capacitance without exhibiting pseudocapacitance behavior, EG’s electrochemical performance in MSCs is limited (Fig. S8 b-d). A maximum volumetric capacitance of 53 F cm-3 is delivered at a low scan rate of 1 mV s-1, decreasing significantly when the scan rate is increased to 100 mV s-1, which is far from satisfactory. Quinones have been already studied as stable and highly capacitive electrode materials for aqueous rechargeable batteries, due to the presence of fast and reversible redox reactions.37,38 Inspired by such promising results, we decided to further functionalize our EG nanosheets with polydopamine coatings to enhance the performance of EG-based MSCs. Dopamine is added into the EG dispersion at pH 8.5, and the polymerization is completed within 24 hours. After the polydopamine 11 ACS Paragon Plus Environment

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coating, PDA-EG shows a significant increase in the nitrogen and oxygen content, as expected from the presence of PDA (Fig. S9). The AFM reveals an average thickness of ~6 nm of PDA-EG, demonstrating the uniform distribution of PDA coating, which can also be observed by HR-TEM of the PDA-EG single flake (Fig. S10). The SEM study shows the average lateral size of PDA-EG is 2-4 μm, inheriting from the EG flake size distribution. The SAED pattern of PDA-EG displays the strong diffraction being nearly identical to the neat EG, thereby suggesting that the PDA coating does not influence the high crystallinity of EG and its associated electronic properties. To investigate the charge transport properties and the influence of PDA coating on the electronic properties of the electrochemically exfoliated graphene, optical pump-Terahertz (THz) probe (OPTP) spectroscopy is employed. As a purely optical approach, THz spectroscopy can provide quantitative insight into the intrinsic charge transport properties (e.g., charge mobility, carrier density, etc.) in the materials of interests in a contact-free fashion,39-44 which is particularly powerful for accessing the electrical properties of low-dimensional materials where electrical contacts are often challenging to deposit for conventional electrical studies. In a typical OPTP measurement, the EGs deposited on the fused silica (using the Langmuir-Blodgett method) are photoexcited by a short femtosecond (~50 fs) laser pulse with a photon energy of ~3.1 eV (400 nm) to generate charge carriers. Subsequently, a single-cycle, freely propagating pulse at THz frequencies (of ~1 ps duration) interacts with the charge carriers and reports back on their photoconductivity in the THz frequency range (as shown in Figure 3(a)). The strength of THz spectroscopy is that it records 12 ACS Paragon Plus Environment

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the time-dependent field E(t) of the THz pulse, rather than only its intensity, at different times after the photoexcitation pulse. It can be shown that the pump-induced change of the THz field ∆E(t) normalized to the transmitted THz field before excitation E is directly proportional to the real part of the THz photoconductivity σ: σ ~ -∆E/E. THz spectroscopy has been intensively used to characterize charge transport in graphene.39, 41, 45 Figure 3b shows the short-lived (picosecond) photoconductivity dynamics of EG and PDA-EG films. The photoexcitation causes injection of charge carriers into the conduction band in the multilayer EG sheets, which recombine quickly. The measured conductivity is determined by the injected charge carrier density Npump, charge mobility µ, and elemental charge e: σ= Npump×e×µ. To allow for a direct comparison of charge transport properties between EG and PDA-EG, THz conductivities of both samples have been normalized to the absorbed photon density NAbs, which, assuming that the quantum efficiency is identical for the two samples, is proportional to Npump. In this manner, the relative change in conductivities directly reflects the change in charge mobility in EG by PDA treatment. As clearly shown in Figure 3b, the electronic properties of the EG samples after PDA coating are well-preserved with at most a ~20% decrease in THz conductivity for PDA-EG compared to that of EG. It is worth noting that the assumption of the equal quantum efficiency for free charges generation in graphene with and without PDA-treatment should be valid, even if multiple hot carrier generation (MHCG)41, 45 take place efficiently in our sample. Although polymer-treatment can introduce an extra momentum (elastic) scattering pathway, it is not expected to affect much faster 13 ACS Paragon Plus Environment

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(inelastic) hot carrier energy loss processes, which determine the MHCG efficiency. Indeed, we observe identical plasma frequencies in the two samples, for a given absorbed photon density (as discussed in the next section). To quantify the electrical transport of photogenerated carrier in EG and PDA-EG, we have determined the complex THz photoconductivity spectra of the samples ~600 fs after excitation (details see SI). As shown in Figure 3 (c-d), the measured conductivity is characterized by positive real photoconductivity and negative imaginary conductivity, both increasing in absolute magnitude with increasing frequency. This type of response is characteristic of charge carriers in low-dimensional systems and can be described by the Drude–Smith (DS) model (lines in Figure 3 (c-d)). The DS model is a phenomenological model which has been successfully applied to describe transport in low-dimensional, confined systems.46,47 As shown in Figure 3c and 3d, the experimental data can be adequately fitted by Drude-Smith model, which reveals the scattering time τe of ~18 fs and ~14 fs for EG and PDA-EG, respectively. The plasma frequencies 𝜔𝑝 normalized to the absorbed photon density are found to be 12 -2 nearly identical (with 𝜔𝐸𝐺 𝑝 = 187.1 THz for absorbed phtodensity of 7.2×10 cm

― 𝐸𝐺 and 𝜔𝑃𝐷𝐴 = 230.7 THz for absorbed photon density of 8.9×1012 cm-2), which is 𝑝

in agreement with our previous assumption of the same quantum yields of free carrier generation in both samples by photo-excitation. Furthermore, employing the effective electron mass m* of ~0.03 me reported in the literature for bilayer graphene, the mobility (µ =

𝑒 ∗ 𝜏𝑒 𝑚∗

) in EG can reach up to 1100 and 860 cm2V-1s-1 for EG and

PDA-EG, respectively. These high mobilities in graphene produced by our 14 ACS Paragon Plus Environment

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electrochemical exfoliation method, illustrate the high quality of the EG flakes. Additionally, the inferred mobility in PDA-EG is concluded to be 22% lower that of EG sample, in a perfect agreement with the dynamic terahertz scans (Figure 3(a)) that revealed a ~20% reduction of conductivity in EG after PDA coating treatment. Although in general, the functionalization of graphene and other two-dimensional materials with organic or inorganic molecules typically leads to the slight decrease of the electronic properties (e.g., decrease of the conductivity) of 2D nanosheets due to the formation of in-plane voids and cavities, such behavior is not considered as a drawback. In fact, many reports have suggested that the presence of structural and chemical defects improves the overall electrochemical performance of 2D nanosheets.48 In order to highlight the electrochemical properties of PDA-EG as a supercapacitor electrode material, we fabricated on-chip in-plane MSCs based on thin PDA-EG films on paper substrates with channels much shorter than those of spray-coated EG (Fig. S8a), the scheme being shown in Figure 4a. Briefly, the as-synthesized PDA-EG was washed repeatedly to remove the tris buffer and unreacted dopamine molecules. Upon subsequent gentle sonication, the PDA-EG flakes were finely dispersed in isopropanol (IPA). Uniform PDA-EG films can be readily obtained on a filter membrane by vacuum filtration of the PDA-EG dispersions. Finally, the PDA-EG films were pressed against target substrates (precleaned SiO2/Si) and kept for 2 hours with the applied pressure. Such “dry transfer” technique provides a uniform and clean approach to obtain PDA-EG films with controlled thickness. The MSC devices were fabricated using well-established 15 ACS Paragon Plus Environment

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lithography techniques. The interdigitated microelectrode patterns were deposited onto the PDA-EG films through a home-made shadow mask, with gold as current collectors (see Fig. S11 for the detailed device geometry). Oxygen plasma was applied to etch away the unprotected part of the film to achieve the desired patterns. A polymer gel electrolyte based on H2SO4/polyvinyl alcohol (H2SO4/PVA) was subsequently drop-cast onto the interdigitated microelectrodes and solidified overnight. The use of gel electrolyte avoids leakage and additional packaging issues of liquid electrolytes. Thus, all solid-state MSCs based on PDA-EG with an in-plane device geometry were realized. To evaluate the electrochemical performance of PDA-EG based MSCs, cyclic voltammetry (CV) and galvanostatic charge/discharge were performed at different scan rates (Figure 4b-g, Fig.S12). Noteworthy, such microdevices demonstrate ultrafast charging/discharging capability and can be operated at ultrahigh speed up to 1000 V s-1, being three orders of magnitude greater than conventional sandwiched-structured supercapacitors.49 Compared with the aforementioned MSCs based on pristine EG, PDA-EG based MSCs (PDA-EG-MSC) show significantly enhanced electrochemical performance. The CV curves are nearly rectangular shaped between the voltage potential of 0 and 1 V, even at a high scan rate of 100 V s-1. This indicates the fine combination of both large electrical-double-layer capacitance from EG and pronounced pseudocapacitance from PDA. Real applicable devices thus prove the undisrupted crystal structures and preserved electronic properties of EG after PDA coating. A maximum areal and volumetric capacitance as high as 2.04 mF cm-2 and 16 ACS Paragon Plus Environment

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340 F cm-3 are delivered at 10 mV s-1 based on 60 nm thick PDA-EG electrode, which compares favorably to state-of-the-art MSCs/ supercapacitor performances based on graphene or other carbon materials, e.g. 212 F cm-3 based on holey graphene framework,50 180 F cm-3 and 410 F cm-3 based on carbide-derived carbon,51,52 1.3 F cm-3 based on onion-like carbon,53 ~3 F cm-3 based on laser reduced GO,8, 10 376 F cm-3 based on high temperature annealing (1000 °C) of graphene hydrogel,54 359 F cm-3 based on selective electrophoretic deposited RGO, 261 F cm-3 based on liquid-mediated densely packed RGO,55 ~500 F cm-3 based on nitrogen-doped mesoporous carbon,56 135 F cm-3 based on fluorine modified graphene,12 and 17.9 F cm-3 based on methane plasma treated GO.49 The evolution of volumetric capacitance of PDA-EG-MSC-60 nm with consecutive scan rates is plotted in Figure 5a (CV curves of PDA-EG-MSC-120 nm shown in Fig. S13). Interestingly, the PDA-EG-MSC-60 nm exhibits an excellent rate capability with capacitance retention of 30%, when the scan rate increases four orders of magnitude from 10 to 105 mV s-1. Such rate capability guarantees a promising power density of the MSC under high operating speeds. As expected, the volumetric capacitance decreases with increasing film thickness, which can be partially attributed to the limited interlayer conductivity of the PDA-EG films. Moreover, in Figure 5b, the logarithmic discharge current exhibits a nearly linear dependence upon scan rates from 10 to 105 mV s-1, suggesting the ultrahigh power delivery of PDA-EG-MSC. The Ragone plot in Figure 5c lists the volumetric energy/power densities of our PDA-EG-MSC together with those of commercially available high-energy lithium 17 ACS Paragon Plus Environment

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thin-film battery (4 V/500 μAh), and high-power aluminum electrolytic capacitor (3 V/300 μF). The PDA-EG-MSC-60 nm provides energy densities of 2.78-9.44 mWh cm-3, which are competitive with that of lithium thin-film battery (1-10 mWh cm−3). Furthermore, a maximum power density of 1000 W cm−3 is also delivered by the same device, which is two orders of magnitude higher than that of conventional sandwiched-structured supercapacitors and one order of magnitude higher than that of an aluminum electrolytic capacitor.9 Such direct comparisons demonstrate the great potential of PDA-EG based reliable and powerful ESSs. In addition, Figure 5d shows the cycling stability of PDA-EG-MSC-60 nm, revealing a capacitance loss identified after 10000 cycles as low as 5%. CONCLUSIONS In summary, we demonstrated an efficient green chemistry approach to produce water-dispersed high-quality graphene nanosheets, via electrochemical exfoliation of graphite. The optimized exfoliation process guarantees the presence of sufficient oxygen-containing groups on the graphene surface, resulting in stable water dispersions, and thus showing the possibilities for further functionalization in aqueous condition. Meanwhile, the electronic properties of graphene are maintained, as evidenced by XPS, Raman, conductivity, and Terahertz studies, and are much better than RGO and highly comparable to the reported electrochemically exfoliated graphene via fast exfoliation. Our EG is likely to replace the dominant position of GO/RGO regarded as the water-dispersible form of graphene, highlighting the 18 ACS Paragon Plus Environment

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potential impact of EG, which to date has been limited by the lack dispersibility and thus processability. MSCs based on graphene flakes functionalized by homogenous PDA coating delivered a high volumetric capacitance of 340 F cm-3 and excellent power density of 1000 W cm-3, which outperformed most of the reported MSCs based on graphene and highly comparable to the dominant commercially available high energy/power devices. Therefore, our EG combines all the desired characteristics which have been pursued during the last decade in RGO. Further optimizations of the electrochemical exfoliation process may improve both the electronic properties and processabilities of this EG, and by using concepts well-established for the in situ functionalization of RGO, various multifunctional composite materials such as conducting polymers-EG, nanoparticles-EG, for energy conversion and storage, optoelectronics, bio-sensing, etc, may be developed. METHODS/EXPERIMENTAL Materials Graphite foil (0.13 mm thick, 99.8%) was purchased from Alfa Aesar. NaOH and Na2SO4 were purchased from VWR chemicals. All the solvents including ethanol, DMF, and IPA were purchased from Fisher Scientific. Dopamine, tris(hydroxymethyl)aminomethane, H2SO4 and PVA were purchased from Sigma-Aldrich. The filtration system was purchased from Merck Millipore. Pretreatment of graphite foil

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The graphite foil was cut into 2×2 cm2 and was fully immersed in liquid nitrogen for 2 minutes, followed by transferred into absolute ethanol immediately and subsequent drying in the oven. The volume expansion was at least 10 times compared with the thickness of untreated graphite foil. There were also some worm-like structures appeared on the surface of graphite foil, which can be beneficial for the electrolyte anions intercalation and the overall exfoliation process. Electrochemical exfoliation of graphite The electrochemical exfoliation of graphite was performed in a two-electrode system, where the pretreated graphite foil was used as an anode, and a piece of platinum foil (2×2 cm2) was employed as a cathode. The distance between the two electrodes was fixed at 1.5 cm. 0.1 M NaOH and Na2SO4 aqueous solution with different ratios (1:0, 25:1, 10:1, and 5:1) was employed as mixed electrolyte. After immersing the two electrodes in the electrolyte, a static positive voltage of 3 V from the power supply system (ISO-Tech) was first applied between the two electrodes for 3 minutes and later increased to 10 V to trigger the whole exfoliation process till the graphite foil was completely “etched”. The product was repeatedly washed by distilled water and ethanol through vacuum filtration. At last, the filtered cake was transferred into distilled water and sonicated for 30 minutes, which resulted in a fine water dispersion of graphene nanosheets. Dopamine functionalization of graphene

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The concentration of the graphene water dispersion was first adjusted to 0.1 mg mL-1. The pH value was adjusted to 8.5 by tris(hydroxymethyl)aminomethane. 5 mg of dopamine was added into 50 mL of such graphene dispersion, with reflux heating at 80°C and vigorous stirring for 24 hours. After polymerization, the product was repeatedly washed by distilled water and ethanol through vacuum filtration and finally dispersed in IPA. MSCs device fabrication The H2SO4/PVA polymer gel electrolyte was prepared by adding 5 g of H2SO4 and 5 g of PVA into 50 mL of distilled water and heated up to 80°C under vigorous stirring until the electrolyte turned transparent. MSCs based on spray-coated EG patterns on paper substrates. Obtained EG was dispersed in IPA with a concentration of 10 mg mL-1, which was directly printed through a shadow mask to achieve large area MSC patterns (without the need of metallic current collectors) on paper substrates, by spray-coating ~3 μm thick film. The EG patterns were achieved by the following steps: First, the EG ink dispersed in IPA was loaded into the chamber of an airbrush. Secondly, the EG ink was spray-coated through a home-made shadow mask (with the MSC device geometry, as shown in Fig. S8a) onto paper substrates to form the patterns. The shadow mask was tightly fastened on the paper substrates to better define the EG patterns. In order to form homogeneous EG patterns, each spray process was carried out in a gentle and quick manner. The diameter of the airbrush nozzle was 0.15 mm and the 21 ACS Paragon Plus Environment

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spray-coating pressure was fixed at 3 bar as supported by nitrogen gas. H2SO4/PVA gel electrolyte was subsequently drop-cast onto the interdigitated EG patterns and solidified overnight. MSCs based on PDA-EG films on SiO2/Si substrates. PDA-EG flakes were dispersed in IPA with a concentration of 0.05 mg mL-1, 2.5 mL and 5 mL of this PDA-EG dispersion were filtrated to obtain solid films of PDA-EG with different thickness (60nm and 120nm). Generally, the PDA-EG films after filtration were pressed against target SiO2/Si substrates and kept for 2 hours with applied pressure, followed by peeling off the filters which left the solid PDA-EG films on SiO2/Si substrates. The interdigitated microelectrode patterns were deposited upon the PDA-EG films through a home-made shadow mask (widths of 210 μm, interspaces of 100 μm), with 90 nm thick gold as current collectors. The deposition rate of gold was controlled at 0.5 Å s-1 with the chamber pressure below 6×10-7 mbar. Oxygen plasma (Plasma System 200-G, Technics Plasma GmbH) was applied to etch away the unprotected part of the film to achieve the desired patterns with 20 sccm O2 flow (chamber pressure 0.2 mbar) at 160W rf power. H2SO4/PVA gel electrolyte was subsequently drop-casted onto the interdigitated microelectrodes and solidified overnight. Thus, all solid-state MSCs based on PDA-EG with an in-plane device geometry were realized. Characterizations

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Z-potential was recorded by DelsaNano Beckman and Coulter system based on diluted graphene water dispersions. X-ray photoelectron spectroscopy (XPS) analysis was performed by Thermo Scientific KAlpha X-ray photoelectron spectrometer, which equipped with an aluminum X-ray source (energy 1.4866 keV), at a vacuum level of 10-8-10-9 mbar in the main chamber. The spot size of the X-ray beam was fixed at 400 μm. Survey spectra were recorded as an average of 10 scans with a pass energy of 200.00 eV and a step size of 1 eV; high-resolution spectra were an average of 10 scans with a pass energy of 50.00 eV and a step size of 0.1 eV. The materials were all analyzed in the form of powder, after drying 6 hours in a vacuum oven with 100°C heating followed by loading into the sample holder. Raman spectra were recorded by a Renishaw spectrometer with 532 nm laser excitation (power of 0.1%), under 100 times objective lens. The silicon peak at 520.3 cm-1 served as a reference for wavenumber calibration. Atomic Force Microscopy (AFM) images were captured by a Veeco Dimension 3100 atomic force microscope under ambient conditions, operating under tapping mode with an antimony (n)- doped silicon cantilever. The thickness distributions of EG and PDA-EG were determined by a statistical analysis of the nanosheets’ AFM images. High-Resolution Transmission Electron Microscopy (HR-TEM) was performed on a JEOL 2100 F microscope working at 200 kV, equipped with a Cs probe corrector 23 ACS Paragon Plus Environment

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and a GATAN Tridiem imaging filter. The samples were prepared depositing a drop of dispersion containing graphene flakes on a TEM grid covered by a lacey carbon membrane. The as-prepared grids were kept overnight under high vacuum in order to remove the eventual solvent residues and possible contaminants. Typical TEM and SEM images were recorded using a Quanta FEG 250 (FEI) system. Cyclic Voltametry (CV) curves of PDA-EG-MSCs were recorded by a CHI 760D electrochemical workstation at different scan rates ranging from 10 mV s-1 to 1000 V s-1, with potential window from 0 to 1 V. CV curves of EG-MSCs were recorded at different scan rates ranging from 1 mV s-1 to 100 mV s-1, with potential window from 0 to 1 V. Calculations regarding volumetric capacitance, energy and power densities were all based on literature reported methods.9, 11 Sample Preparation. All the substrates were cleaned by subsequent ultrasonication in acetone and isopropyl alcohol for 20 minutes respectively, followed by drying with nitrogen flow. The samples for AFM, SEM, Raman, and THz were prepared by transferring the compressed film on top of water surface onto target substrates by a Langmuir Schaefer system (KSV minitrough) from a graphene dispersion with a concentration of 0.1 mg mL-1. Film conductivity. The electrical conductivity S (in S cm-1) of the EG films was calculated by S=107/(Rs×d), where the sheet resistance of the film Rs was measured by a four-probe system (Jandel Model RM3000), and d is the thickness of the film in nm. 24 ACS Paragon Plus Environment

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Figures

Figure 1. Electrochemical exfoliation of graphite and the obtained graphene dispersions in water. a) Schematic illustration of the electrochemical exfoliation process employed towards water-dispersed graphene and subsequent functionalization with polydopamine. b) Experimental setup for electrochemical exfoliation of graphite. c) Photographs of graphene dispersion in water. d) Tyndall effect of graphene water dispersion. e) Salt effect of graphene water dispersion, which suggests by the addition of sodium chloride, the stabilization of the graphene water dispersion is severely disrupted.

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Figure 2. Spectroscopy and morphological characterizations of obtained graphene flakes. a) High-resolution XPS of the C 1s spectrum of EG. b) Raman spectra (excited by 532 nm laser) of a bilayer-flake of EG. c) AFM image of EG on SiO2 substrates. d) Statistical study of the thickness distribution of EG by AFM. e) Typical TEM image of the specimen deposited on a TEM grid, with a large field of view. f-g) HR-TEM images of EG, the squared box area indicates the selected flake with a zoomed field of view for the SAED measurement. h) SAED pattern of the corresponding EG fragment. i) SEM image of the specimen deposited on a SiO2/Si substrate with a large field of view.

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Figure 3. THz studies on the ultrafast charge carrier dynamics in graphene and polydopamine-graphene. a) illustrates the optical-pump THz probe spectroscopy. b) compares the ultrafast THz conductivity in both samples. The THz conductivity is normalized to the absorbed photon densities to allow for a quantitative comparison. The inset shows the fluence dependent THz conductivities. c-d) show the frequency conductivity of photogenerated carriers and corresponding Drude-Smith model calculations, from which the charge carrier scattering time, and corresponding mobility is inferred.

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Figure 4. Polydopamine-graphene based micro-supercapacitor device fabrication and characterization. a) Schematic illustration of the device fabrication of MSCs based on PDA-EG electrodes on silicon wafer. b-g) CV curves of PDA-EG-MSC-60 nm performed at different scan rates ranging from 10 mV s-1 to 1000 V s-1, with potential window from 0 to 1 V.

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Figure 5. Summary of electrochemical performance of polydopamine-graphene micro-supercapacitors. a) Evolution of the volumetric capacitance versus scan rate based on two different PDA-EG film thicknesses. b) Discharge current as a function of scan rate based on PDA-EG-MSC-60 nm device. c) Ragone plot of commercial Li thin-film battery, Electrolytic capacitor, and PDA-EG-MSC based on two different PDA-EG film thickness. d) cycling stability of PDA-EG-MSC-60 nm device over 10000 cycles, at scan rate 20 V s-1. Inset shows the CV curves of the 1st and 10000th cycle.

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ASSOCIATED CONTENT Supporting Information. Supporting figures are available in the Supporting Information. The authors declare no competing financial interest. AUTHOR INFORMATION Corresponding Author Artur Ciesielski [email protected]; Paolo Samorì [email protected] Author Contributions Z.L., A.C., and P.S. conceived and designed the project. Z.L. performed the electrochemical exfoliation of graphite, and the subsequent processing and characterization of obtained graphene nanosheets, as well as the micro-supercapacitor fabrication and evaluation. H.Z., M.B., and H.I.W. performed THz measurements. M.E. performed the TEM, SEM and XPS study. W.B. and O.E. performed the high-resolution TEM measurements. H.Q. involved in the electrical characterization and Raman spectroscopy of EG. ACKNOWLEDGMENT Dr. Rafael Furlan de Oliveira and Dr. Yifan Yao are acknowledged for enlightening discussions. Dr. Simone Silvestrini is acknowledged for the help of Z-potential measurements. We acknowledge the financial support by the European Commission through the Graphene Flagship Core 2 project (GA No. 785219), the AMI project funded by the ERA-NET EuroNanoMed III programme, the European Union and the Agence Nationale de la Recherche (ANR) GA-ANR-17-ENM3-0001-01, the ANR 30 ACS Paragon Plus Environment

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through the Labex project CSC (ANR-10-LABX-0026 CSC) within the Investissement d’Avenir program (ANR-10-120 IDEX-0002-02), and the International Center for Frontier Research in Chemistry (icFRC).

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