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Article

Synthesis of Low-Crystalline MnO2/MXene Composites for Capacitive Deionization with Efficient Desalination Capacity

by
Zhumei Sun
1,
Jun Peng
2,
Shu Yang
3,
Riya Jin
1,
Changcheng Liu
1 and
Que Huang
1,*
1
School of Environmental and Safety Engineering, North University of China, Taiyuan 030051, China
2
Changsha Research Institute of Mining and Metallurgy Co., Ltd., Changsha 410012, China
3
College of Environment and Safety Engineering, Qingdao University of Science and Technology, Qingdao 266042, China
*
Author to whom correspondence should be addressed.
Metals 2023, 13(6), 1047; https://doi.org/10.3390/met13061047
Submission received: 31 March 2023 / Revised: 12 May 2023 / Accepted: 13 May 2023 / Published: 30 May 2023
(This article belongs to the Special Issue Manufacturing and Characterization of Metallic Electrode Materials)
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Abstract

:
MXene has drawn widespread attention as a potential material for electrode use in capacitive deionization (CDI). However, the applications of MXene are limited by its property of low electrical capacity. Herein, a MnO2/MXene composite was firstly evaluated in a capacitive deionization system, in which the MnO2 acts as intercalation-type pseudocapacitive electrodes to enhance the electrical capacity, and MXene provides an electron conduction highway network that improves the charge transfer of the MnO2. The result showed that the low-crystallinity MnO2 with irregular particles was well-distributed on the surface of the MXene. The desalination capacity of 30.5 mg·g−1 is achieved at a voltage window of 1.2 V, which was higher than that of the reported pure MXene and MnO2. The electrical double-layer (EDL) capacitive and the diffusion-controlled processes are the main charge storage mechanisms, and the EDL contribution provides 50.3% to the total capacitance. This result suggests a promising direction for further applying a MnO2/MXene composite in CDI.

1. Introduction

Freshwater scarcity brought on by population growth and economic needs has grown into a serious problem in recent years [1,2]. Developing low-energy techniques that can efficiently generate large-scale fresh water by using the abundance of brackish or sea water on earth [3,4,5] is believed to be a promising approach to solve this serious problem. Interest in the use of brackish water with salinity between 0.5 and 30 g/L is growing. Conventional desalination technologies such as reverse osmosis, electrodialysis, multi-effect distillation, and multi-stage flash evaporation are just a few of the technologies that have been suggested for this purpose. However, their widespread use has been constrained thus far by their high energy consumption and complex operation [6].
Capacitive deionization (CDI) emerged as the most promising method among a variety of desalination technologies because it is one of the most reliable and affordable methods for desalinating water [7]. The advantages of CDI over other conventional technologies include low operation voltage, high salt removal capacity, minimal chemical demand, and the absence of secondary wastes. The foundation of CDI is the application of an external electrostatic field between electrodes to drive charged species toward electrodes with opposing charges. When the voltage is short-circuited or reversed, charged ions are released from the electrodes, and the electrode is regenerated for cycle use. The electrical double layer (EDL) that forms between the solution and electrode contact can attract and hold the charged species. The EDL capacity as a result of the electrostatic attraction force between the ions and the electrode is a crucial factor contributing to the adsorption capacity of capacitive deionization (CDI) [8,9,10]. Therefore, the salt adsorption capacity (SAC) of the carbon electrodes is often limited by both the available surface area and pore structure [11]. Therefore, the theoretical maximum desalination capacities of conventional CDI cells were only ∼10–15 mg·g−1. Many researchers have concentrated on intercalation-type pseudocapacitive materials or Faradaic materials that react with the ions in a solution to continue Faradic reactions in order to get around the SAC limitation of carbon electrodes [12,13]. Pseudocapacitance, or the features of metal oxide capacitance, results from the lattice spacing that allows for ion storage during faradaic electron transit in various metal states. Currently, two-dimensional (2D) transition metal nitrides/carbides (MXene) are one of the materials with the most potential for electrode use in CDI due to its high electrical conductivity and hydrophilic surfaces, and good ion intercalation–deintercalation reversibility in aqueous media [14]. The layered MAX phases (Mn+1AXn) (where M is an early transition metal, A is a group A element (usually Al or Si), X is carbon and/or nitrogen, and n = 1, 2, or 3) are used to create MXenes by etching out the A layer. MXenes are represented as Mn+1XnTx, where x is the number of terminating groups and T refers to the surface termination groups (−O, −OH, and −F) left behind after the etching process. Furthermore, T acts as active sites for crystallization and is beneficial for conductivity, ion insertion, and the extraction process, leading to the improved electrochemical performance. Due to their qualities, they can be employed as great pseudocapacitors to significantly enhance the electrochemical performance and desalination performance of electrode materials [15,16] as well as perfect conducting strips to couple discrete Faradaic or pseudocapacitive materials. For the first time, Srimuk et al. suggested using Ti3C2-MXene as the CDI electrode material, with a desalination capacity of 13 mg·g−1 [17]. Even though the capacity is somewhat low due to the multilayer structure caused by the lack of a delamination process, it demonstrates that MXene can be employed for CDI as a novel intercalation-type pseudocapacitive electrode. Instead of Ti3C2-MXene, Srimuk et al. tested Mo1.33C-MXene electrodes, which have a 15 mg·g−1 capacity [18]. Although the above MXene electrode performs desalination more effectively than a carbon electrode, the adsorption capacity of MXene is still not very great.
To enhance the electrochemical energy storage performance, intercalation-type pseudocapacitive electrode materials are incorporated to increase the surface area and provide additional pseudocapacitance, such as manganese dioxide (MnO2) [19,20,21], Prussian blue and its analogs [22,23,24], Na3V2(PO4)3 [25], Co3O4 [26], Fe3O4 [27], and NaTi2 (PO4)3 (NTP) [28]. One of these materials, MnO2, is particularly interesting for research because it is widely available, inexpensive, and has good cycle stability [29]. Theoretically, MnO2 has a substantially larger capacitance (1370 F·g−1) than materials based on carbon. Manganese dioxides can be categorized into various crystalline phases depending on the orientation of the MnO6 octahedra and lattice defects, such as α-MnO2 (hollandite), β-MnO2 (pyrolusite), R-MnO2 (ramsdellite), γ-MnO2 (intergrowth of and R), and δ-MnO2 (birnessite). Electrodes containing MnO2 intercalation typically have a higher ion adsorption capacity than porous carbon materials alone. However, with the exception of a few unique situations with incredibly low loading of the active material, the specific capacitance of MnO2 measured experimentally is significantly lower than the theoretical value. The discrepancy has been attributed to the poor electrical conductivity and limited surface area of MnO2, which places a restriction on the pseudocapacitive capability of material. To enhance the performance, forming MnO2-based hybrid structures with conductive materials is a promising implementation approach. Therefore, combining the positive characteristics of MnO2 and MXene is an effective strategy for improving the specific capacitance, rate performance, and cycle life of electrode materials. MnO2/Mxene composites have recently been created by numerous researchers and effectively employed in supercapacitors [30,31,32], batteries [33], catalysis [34], the removal of heavy metal ions [35,36], and other fields. However, no previous study has used MXene/MnO2 composite materials as electrodes for achieving desalination through electrosorption.
Herein, we demonstrate a novel strategy for loading MnO2 on MXene to obtain a MnO2/MXene composite that exhibits the advantageous characteristics of both MnO2 and MXene. These qualities include the high electrical conductivity of MXene, which helps MnO2 transfer charges more effectively, and the large theoretical capacitance of MnO2, which supports reversible ion intercalation and deintercalation for high desalination rates and capacities. Simultaneously, the structure and morphology of the MnO2/MXene composite was characterized by X-ray diffraction (XRD), field-emission scanning electron microscopy (FESEM), and X-ray photoelectron spectra (XPS). Furthermore, the desalination and electrochemical performance of the MnO2/MXene electrode was carefully studied.

2. Experimental Section

2.1. Materials

All chemicals were purchased from Sinopharm Chemical Reagent Co., Ltd. (Shanghai, China) in analytical purity and used in the experiments directly without any further purification. Ti3AlC2 MAX was purchased from Jilin 11 Technology Co., Ltd. (Changchun, China). All the solutions were prepared in high-purity de-ionized water (DIW).

2.2. Synthesis

2.2.1. Synthesis of the Ti3C2 MXene

Delaminated Ti3C2Tx was prepared by etching Ti3AlC2. A total of 2 g of LiF (98.5%) was added to 30 mL of HCl solution (9 M), and 2 g of Ti3AlC2 was added to the above solution under stirring for 48 h at 40 °C. Then, the mixture was washed with water using centrifugation until the pH of the supernatant was above 6. The dark green supernatant was collected to obtain the delaminated MXene suspension. This MXene suspension was filtered to measure the concentration of the delaminated MXene. Delaminated Ti3C2Tx was then obtained by freeze-drying.

2.2.2. Synthesis of MnO2/MXene

A total of 2 mL 0.02 mol/L MnSO4·H2O aqueous solution was slowly dropped into 25 mL 0.04 mol/L KMnO4 aqueous solution and stirred for 10 min. The 80 mL (2 mg/mL) MXene colloidal solution was added into the above mixed solution, ultrasonicated for 10 min. The dispersion was transferred to a Teflon-lined stainless-steel autoclave for hydrothermal reaction at 140 °C for 2 h. The MnO2/MXene product was washed by vacuum filtration with DIW. The washed materials were collected after vacuum drying at 40 °C for 24 h.

2.2.3. Characterization

The samples microstructure analysis was conducted with scanning electron microscopy (SEM, MIRA4 LMH, TESCAN, Brno, Czech Republic). Further, relative contents of elements were figured out using energy dispersive spectrometer (EDS, Ultim Max 40, TESCAN) and mapping. An X-ray diffractometer (XRD, D8 Advance, Bruker, Billerica, MA, USA) was utilized to characterize the composition and crystallographic structure. The surface areas and pore diameters were calculated by the Brunauer–Emmett–Teller (BET, ASAP 2460, Micromeritics) method. Elements were studied by an X-ray photoelectron spectroscopy (XPS, Escalab 250Xi, Thermo Scientific, Bend, OR, USA) using an A1 Kα X-ray source at a pass energy of 160 eV for survey scans and 40 eV for higher solution scans.

2.2.4. Electrochemical Measurement

The cyclic voltammetry (CV), galvanostatic charge–discharge (GCD), and electrochemical impedance spectroscopy (EIS) were measured in 1 M NaCl solution by Metrohm Ltd. (Multi Autolab M204, Herisau, Switzerland) electrochemical workstation. The three-electrode system consists of a MnO2/MXene electrode (working electrode), an activated carbon electrode (counter electrode), and a Ag/AgCl (3 M KCl) electrode (reference electrode). The working electrodes were fabricated starting with mixing the MnO2/MXene materials, polyvinylidene difluoride (PVDF), and carbon black with a mass ratio of 80:15:5, all dispersed in N-methyl-2-pyrrolidone (NMP). Then, the obtained slurry was coated on a carbon paper with a size of 2 cm × 1 cm and then dried at 60 °C for 6 h. The specific capacitance of the electrodes was determined by Equation (1),
C s = 1 2 v × m × Δ V I d V
where Cs is specific capacitance (F·g−1), ∫IdV is the integrated area of the CV curve (AV), and ΔV is potential difference window (V), ν is potential scan rate (V·s−1), and m is the mass of electrode material (g).

2.2.5. Desalination Performance Experiments

The electrode materials of the cathode and anode were MnO2/MXene and activated carbon, respectively. A total volume of 40 mL of NaCl solution was continuously circulated within a homemade CDI cell through a peristaltic pump at a flow rate of 10 mL min−1. The CDI cell was composed of a pair of electrodes separated by a silica gel gasket and acrylic plate. The cathode and anode used were, respectively, composed of MnO2/MXene and AC (activated carbon) with the distance of 1.0 mm. The desalination experiments were conducted at a constant cell voltage of 1.2 V with a starting NaCl concentration ranging from 50 to 5000 mg L−1 (0.85–85.5 mM). The salt concentration change was measured by monitoring the effluent conductivity with a DDSJ-308A conductivity meter (INESA Scientific Instrument Co., Shanghai, China). After the effluent conductivity decreased to a constant, the electrodes were then regenerated by applying an inversed voltage until the effluent conductivity was constant. The desalination capacity (Γ) is calculated as follows.
The salt adsorption capacity (SAC mg·g−1) was calculated according to the following formulas:
S A C = ( C 0 C e ) × V m
where V is the volume of circulated solution (L), C0 (mg·L−1) and Ce (mg·L−1) are the initial and equilibrium concentrations of ions, respectively, and m is the mass of a pair of electrodes (g).

3. Results and Discussion

3.1. Materials Characterization

Figure 1 schematically depicts the MnO2/MXene composite preparation process. To begin with, stacked-layer structured Ti3C2 MXene (m-Ti3C2Tx) was produced by etching layered Ti3AlC2 MAX with LiF/HCl while stirring to remove the Al layers and widen the interlayer space of the MAX phase [37]. Then, the m-Ti3C2Tx was delaminated by centrifuging to obtain the delaminated MXene. Moreover, MnO2 was grown on MXene using the hydrothermal method, and the MnO2/MXene composite was then successfully synthesized. The morphologies of the prepared MXene and MnO2/MXene composite were investigated via field-emission scanning electron microscopy (FESEM). Figure 1 shows that multilayer Ti3C2Tx becomes few-layered or even single-layered after the ultrasonic delamination process. The irregular particle MnO2 was grown over the MXene 2D layers (Figure 2b), which act as a conducting layer coupling each individual MnO2 particle, thus forming a plane-to-line (Ti3C2Tx-to-MnO2) conducting network. The elemental analysis was performed on the MnO2/MXene composite using energy-dispersive X-ray spectroscopy (EDS). The Mn:O ratio is 1:2.2, confirming the formation of MnO2. A slightly higher O content than 1:2 is due to the presence of TiO2 which agreed well with the XRD result. However, the Ti:O ratio is 2.27:1, which indicates that the content of Ti is much higher than O, and the TiO2 is only very little. The formation of the MnO2/MXene composites was also verified via an elemental mapping analysis (Figure 2). The Mn, Ti, and O signals were found to be uniformly distributed based on the MnO2 and MXene on the surface of the MnO2/MXene composite. The successful and tight adhesion of MnO2 to the Ti3C2Tx surface is thus demonstrated.
A more detailed phase structure of the MnO2/MXene composite was studied via XRD analysis (Figure 3a); the diffraction peaks of MnO2/MXene are too broad to be detected with low intensity, which is probably ascribed to its lower crystallinity. Moreover, the weak characteristic peak corresponding to TiO2 was observed in the XRD pattern of the MnO2/MXene composite, suggesting that the MXene was oxidated during fabricating the composite. The surface chemical composition and chemical valence states of the MnO2/MXene composite were analyzed via XPS. The survey spectra of the MnO2/MXene composite shows the characteristic peaks of C 1s (285 eV), O 1s (530 eV), Ti 2p (458 eV), and Mn 2p (643 eV) (Figure 3b). The MnO2 phase is present in the composite and is consistent with the XRD data because the value of the Mn 2p peaks with a spin-energy separation of 11.8 eV indicates that the main oxidation state of Mn is +4 (Figure 3c). [30]. Figure 3d shows the high-resolution Ti 2p XPS spectra of the MnO2/MXene composite. The 2p3/2 and 2p1/2 orbits of Ti3+ in the MXene are located at 457.8 and 463.2 eV, respectively. Additionally, the peaks at 455.9 and 462.2 eV can be attributed to the Ti–O (2p3/2) and Ti–O (2p1/2) bonds, respectively, which originate from the oxygen-containing groups attached to the surface of the MXene. These XPS results indicate that MXene is present in the MnO2/MXene composite. Moreover, as observed from the high-resolution Ti 2p XPS spectra of the MnO2/MXene composite, the contents of Ti2+ and Ti3+ are larger than Ti–O, indicating that Ti3C2 MXene partially oxidized to TiO2. The reason the Ti3C2 MXene peaks were not detected by the XRD is maybe the low content. To investigate the pore structure of the MnO2/MXene composite, their nitrogen adsorption–desorption was measured, and the corresponding isotherm is shown in Figure 3e. The sample displays significant hysteresis loops between 0.45 and 1.0 P/P0, demonstrating the existence of a mesoporous structure. The pore-size distributions of the samples calculated from the desorption isotherms using the Barret–Joyner–Halenda (BJH) method are shown in the inset of Figure 3e. The majority of the pores of MnO2/MXene lie in the range of 8–12 nm. As a result, the mesoporous MnO2/MXene composite is predicted to have good electrochemical characteristics [38]. The BET surface area calculated for MnO2/MXene is 184.59 m2/g.

3.2. Desalination Performance

Figure 4a shows the desalination capacity of MnO2/MXene in a solution with an initial charge concentration of 1000 mg·L−1 at 1.2 V. The rapid desalting phase is 5 min, and the desalination capacity is over 50% of the maximum desalination capacity, and then the desalination capacity continues to increase with a slow absorption rate of 5–60 min. The maximum desalination capacity is 30.25 mg g−1 for the total mass of active materials, which is higher than those of the reported pure Ti3C2Tx (13.58 mg g−1) [17] and MnO2 electrode (9.93 mg g−1) [39]. Further experiments were conducted in solutions with various concentrations (Figure 4b). Langmuir and Freundlich isotherms were used to validate the experimental data. The Freundlich model (R2 > 0.9829) fits better than the Langmuir model (R2 > 0.8866), which indicates a multilayer adsorption mechanism on the MnO2/MXene.
Ragone plots, which carefully balance the SAC and ion adsorption rate, were used to further demonstrate the desalination performance of the MnO2/MXene electrodes (SAR). Figure 4c shows that the MnO2/MXene curves shift in the upper right direction with increasing initial concentration. This shows that when the concentration rose, the ionic conductivity increased, creating circumstances that made the rapid passage of ions to the electrode more likely; therefore, the MnO2/MXene electrodes show excellent desalination and rate performance. Additionally, MnO2/MXene (3.77 mg g−1 min−1) exhibits a higher desalination rate than Ti3C2Tx (0.91 mg g−1 min−1). This is due to the composite structure of the MnO2 and Ti3C2Tx in which MXene can provide a conductive channel for ultrafast electron transport [40]. The high desalination rate of the MnO2/MXene electrode in this work strongly suggests that it has a good kinetic performance, which is crucial in the actual desalination process [41]. Based on the above analysis, the excellent desalination performance and electrochemical performance of the MnO2/MXene electrode can be attributed to the following reasons.
(1) Owing to its excellent conductivity, MXene provides an electron conduction highway network for MnO2, forming a plane-to-point conduction network, which not only considerably improves the ability of MnO2 to participate in desalination but also effectively reduces the ion diffusion path, affording a high desalination capacity, a rapid desalination rate, and improved electrochemical desalination reaction kinetics.
(2) The low-crystallinity ε-MnO2 and δ-MnO2, as confirmed via XRD, have abundant grain boundaries and ion diffusion channels owing to their disordered structure, which considerably improves the electrochemical performance.
(3) MXene can store charge through the double-layer principle by relying on surface ion adsorption, thereby providing an effective capacitance contribution, which is conducive to improving the desalination performance.

3.3. Electrochemical Properties

The electrochemical properties of the as-prepared MnO2/MXene electrode were evaluated via CV and GCD tests using a three-electrode system in a 1 M NaCl solution. Figure 5a shows the CV curves of the MnO2/MXene electrode at different scan rates in a fixed potential range from −0.1 to 0.3 V. Clearly, the MnO2/MXene electrode exhibits pseudo- rectangular-shaped CV curves without obvious redox peaks, strongly suggesting the simultaneous contribution of the electrical double-layer formation and Faradaic redox process to the specific capacitance of the present materials. Moreover, the shape of the CV curves tends to change from quasi-rectangular to spindle, indicating the occurrence of a rapidly reversible Faradaic reaction for pseudocapacitive materials [42,43], which is favorable for enhancing the desalination capacity. With the increase in the scan rate, symmetric oxidation and reduction peaks can be observed at a scan rate as high as 100 mV s−1 for the MnO2/MXene, indicating the excellent reversibility of this electrode.
To further investigate the electrochemical kinetics and charge storage mechanisms of the two electrodes, the capacitive and diffusion contributions to the current response are quantitatively evaluated. The two-phase charge control can be determined based on the relationship between the measured current (i) and the scan rate (v) from the CV curves [44]:
i = a v b ,
log i = b log v + l o g ( a ) ,
where a and b are constants. On composite charge storage devices, b values are typically employed to evaluate the partial impact of electrochemical double-layer capacitors or pseudocapacitors. This behavior resembles that of a battery because when the proton bulk transport mechanism occurs and the b value just misses 0.5 at a lower voltage, a diffusion-controlled redox reaction occurs. Because the responsive current is dominated by the surface capacitive contribution when the b value approaches 1 with a further increase in potential, the behavior is similar to that of a supercapacitor and includes both double-layer capacitive and surface redox reactions. At b = 1, fast capacitive charge storage is expected, whereas b = 0.5 implies that the current flow is governed by a diffusion-limited process [45]. The b value for MnO2/MXene is 0.5952 (Figure 5e), indicating both the capacitive contribution and diffusion-controlled contribution for the MnO2/MXene electrode. The contributions of the two processes to the total capacitance are further calculated (Figure 5f) by analyzing the current response at a particular potential based on Dunn’s method [46,47]:
i V = k 1 v + k 2 v 0.5
where k1v and k2v0.5 account for the capacitive and the diffusion-controlled processes (charge transfer), respectively. The slope and interception represent the k1 and k2 values, respectively. The plots in Figure 5c clearly show that the percentage of the capacitive contribution increases from 50.26% to 89.49% for the MnO2/MXene electrode with an increasing scan rate. This is because redox reactions are limited at high scan rates; thus, the diffusion-controlled process becomes negligible, whereas the capacitive process contributes more to the capacitance as the scan rate increases. Further, of the MnO2/MXene electrode, the capacitive process contributes approximately 50.3% of the total capacitance according to Trasatti’s method [48]. This indicates the occurrence of possible violent redox reactions in the MnO2/MXene electrode. This result further proves that the electrochemical activity of the MnO2/MXene electrode is due to the EDLC and the ion intercalation reactions. Interestingly, the surface area of MnO2/MXene is larger than other reported samples, while the capacitive process contribution and diffusion control contribution are basically the same, which further indicates the occurrence of violent redox reactions in the MnO2/MXene electrode. Thus, MnO2/MXene is a pseudocapacitive electrode that may remove Na+ ions through intercalation/deintercalation along with the Faradaic redox reaction in the transformation of the +4 and +3 oxidation states of Mn (Equation (6)) [49].
(MnO2) + Na+ + e ↔ MnOONa
The GCD curves of the two MnO2/MXene electrodes at current densities from 0.05 to 1 A g−1 are shown in Figure 5d. All the GCD curves are the nearly symmetric shape of the charge–discharge curves recorded at different current densities, indicating the fast ion transport within the electrodes, superior reversible redox reaction, and good electrochemical capacitive characteristic. Additionally, at the start of the discharge curve, these charge–discharge curves show a very small voltage, indicating the very low inner resistance and ion diffusion resistance between the electrode material and salt electrolyte [50]. Therefore, in this composite, the enhancement of the charge storage capacity is significantly dependent on the effective charge transfer at the interface between the MXene and MnO2.
EIS measurements were performed to investigate the electrochemical properties of the electrode in detail. The EIS results of the MnO2/MXene electrode are shown in Figure 5e. A curve shows an Ohmic capacitance resistance in the high-frequency region and a diffusion tail in the low-frequency region, which correspond to the charge transfer (Rct) and ion diffusion processes, respectively. Small semicircles are related to low Rct. The Rct value of the MnO2/MXene electrode is 0.804 Ω, suggesting fast charge transport for both electrodes. The low-frequency line of the MnO2/MXene electrode is subvertical, implying a small Warburg impedance and good capacitance characteristics. Such an excellent electrochemical performance makes us more interested in exploring their application in CDI and then laying the foundation for practicality.

4. Conclusions

In the current study, MnO2 was successfully loaded on MXene to obtain a MnO2/MXene composite. The obtained MnO2/MXene composite exhibited low crystallinity and good electrochemical performance. As demonstrated, MnO2/MXene exhibits a better desalination performance than the reported pure MnO2 and MXene electrode materials, including a maximum deionization rate of 3.77 mg g−1 min−1 and a desalination capacity of 30.25 mg·g−1. The EDL capacitive and the diffusion-controlled processes are the main charge/ion storage mechanisms, and the capacitive contribution provides 50.3% to the total capacitance. These results provide insight into the electrochemical adsorption mechanism of the MnO2/MXene electrode and offer guidance to further improve their desalination capacity.

Author Contributions

Z.S.: Data curation, Formal Analysis, Writing—original draft; J.P.: Software, Visualization; S.Y.: Investigation, Methodology; R.J.: Conceptualization, Resources.; C.L.: Funding Acquisition, Project Administration; Q.H.: Supervision, Validation, Writing—Review and Editing. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the National Natural Science Foundation of China [52004035] and the China Postdoctoral Science Foundation [2021M703651].

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Schematic of the synthesis of the composites and their application in CDI.
Figure 1. Schematic of the synthesis of the composites and their application in CDI.
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Figure 2. (a,b) FESEM images of MXene and MnO2/MXene and (c) with the corresponding EDS elemental mappings of Mn, O, and Ti.
Figure 2. (a,b) FESEM images of MXene and MnO2/MXene and (c) with the corresponding EDS elemental mappings of Mn, O, and Ti.
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Figure 3. (a,b) XRD patterns and XPS survey spectra of MnO2/MXene composites, (c,d) high-resolution Mn 2p and Ti 2p XPS spectra, (e) nitrogen adsorption–desorption isotherms and pore diameter distribution of MnO2/MXene.
Figure 3. (a,b) XRD patterns and XPS survey spectra of MnO2/MXene composites, (c,d) high-resolution Mn 2p and Ti 2p XPS spectra, (e) nitrogen adsorption–desorption isotherms and pore diameter distribution of MnO2/MXene.
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Figure 4. Desalination performance. (a) Electrosorption curves obtained using a NaCl solution (concentration: 1000 mg L−1), (b) fitting curves obtained using the Langmuir model, (c) Ragone plots at various operating concentrations.
Figure 4. Desalination performance. (a) Electrosorption curves obtained using a NaCl solution (concentration: 1000 mg L−1), (b) fitting curves obtained using the Langmuir model, (c) Ragone plots at various operating concentrations.
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Figure 5. Electrochemical properties. (a) CV curves; (b) log-log plots; (c) capacitive and diffusion-controlled contributions at different scan rates; (d) GCD curves; (e,f) EIS spectra.
Figure 5. Electrochemical properties. (a) CV curves; (b) log-log plots; (c) capacitive and diffusion-controlled contributions at different scan rates; (d) GCD curves; (e,f) EIS spectra.
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Sun, Z.; Peng, J.; Yang, S.; Jin, R.; Liu, C.; Huang, Q. Synthesis of Low-Crystalline MnO2/MXene Composites for Capacitive Deionization with Efficient Desalination Capacity. Metals 2023, 13, 1047. https://doi.org/10.3390/met13061047

AMA Style

Sun Z, Peng J, Yang S, Jin R, Liu C, Huang Q. Synthesis of Low-Crystalline MnO2/MXene Composites for Capacitive Deionization with Efficient Desalination Capacity. Metals. 2023; 13(6):1047. https://doi.org/10.3390/met13061047

Chicago/Turabian Style

Sun, Zhumei, Jun Peng, Shu Yang, Riya Jin, Changcheng Liu, and Que Huang. 2023. "Synthesis of Low-Crystalline MnO2/MXene Composites for Capacitive Deionization with Efficient Desalination Capacity" Metals 13, no. 6: 1047. https://doi.org/10.3390/met13061047

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