Electrochemical nitrate reduction in acid enables high-efficiency ammonia synthesis and high-voltage pollutes-based fuel cells

Most current research is devoted to electrochemical nitrate reduction reaction for ammonia synthesis under alkaline/neutral media while the investigation of nitrate reduction under acidic conditions is rarely reported. In this work, we demonstrate the potential of TiO2 nanosheet with intrinsically poor hydrogen-evolution activity for selective and rapid nitrate reduction to ammonia under acidic conditions. Hybridized with iron phthalocyanine, the resulting catalyst displays remarkably improved efficiency toward ammonia formation owing to the enhanced nitrate adsorption, suppressed hydrogen evolution and lowered energy barrier for the rate-determining step. Then, an alkaline-acid hybrid Zn-nitrate battery was developed with high open-circuit voltage of 1.99 V and power density of 91.4 mW cm–2. Further, the environmental sulfur recovery can be powered by above hybrid battery and the hydrazine-nitrate fuel cell can be developed for simultaneously hydrazine/nitrate conversion and electricity generation. This work demonstrates the attractive potential of acidic nitrate reduction for ammonia electrosynthesis and broadens the field of energy conversion.

Most current research is devoted to electrochemical nitrate reduction reaction for ammonia synthesis under alkaline/neutral media while the investigation of nitrate reduction under acidic conditions is rarely reported.In this work, we demonstrate the potential of TiO 2 nanosheet with intrinsically poor hydrogenevolution activity for selective and rapid nitrate reduction to ammonia under acidic conditions.Hybridized with iron phthalocyanine, the resulting catalyst displays remarkably improved efficiency toward ammonia formation owing to the enhanced nitrate adsorption, suppressed hydrogen evolution and lowered energy barrier for the rate-determining step.Then, an alkaline-acid hybrid Znnitrate battery was developed with high open-circuit voltage of 1.99 V and power density of 91.4 mW cm -2 .Further, the environmental sulfur recovery can be powered by above hybrid battery and the hydrazine-nitrate fuel cell can be developed for simultaneously hydrazine/nitrate conversion and electricity generation.This work demonstrates the attractive potential of acidic nitrate reduction for ammonia electrosynthesis and broadens the field of energy conversion.
Ammonia (NH 3 ) is an essential raw ingredient for fertilizers pharmaceutical, and nitrogen-containing chemicals industries [1][2][3] .Under the background of "hydrogen energy" and "carbon neutrality", NH 3 also becomes an ideal energy and hydrogen carrier and a perspective transportation fuel alternative with a high gravimetric energy density 4,5 .Recently, electrochemical nitrate reduction reaction (NO 3 − RR) for NH 3 synthesis has received much attentions 6,7 .The NO 3 − has good availability and rich abundance in nature, especially in wastewater.Converting NO 3 − into NH 3 is highly attractive for the treatment of NO 3 − -containing wastewater and "turn waste into wealth" 8,9 .In addition, NO 3 − RR exhibits far superior NH 3 -yield efficiency and much lower energy consumption than nitrogen reduction and traditional Haber-Bosch process, respectively, owing to the enhanced adsorption behavior and low activation energy of NO 3 − on the catalyst surface [10][11][12] .NO 3 − RR, therefore, is of great significance for environmental protection, green NH 3 production, and energy utilization.
Extensive efforts have been devoted to exploring selective electrocatalysts for the NO 3 − RR in alkaline/neutral media 7,13,14 .Although the high Faradic efficiencies (FE) towards NH 3 (>90%) have been achieved on state-of-art catalysts, the nitrite (NO 2

−
) is usually generated as the main byproduct at the beginning and large overpotentials are required to achieve the best NO 3 − -to-NH 3 performance.It is also suggested that in situ generated NH 3 exists in gaseous form at the electrode surface due to the increased local pH (mostly over 10) and may be released from the alkaline/neutral electrolyte, which needs an acid adsorption process for NH 3 capture 15,16 .According to the reaction equation of NO 3 − + 6H 2 O + 8e − → NH 3 + 9OH − in alkaline/neutral media, the NO 3 − RR involves nine proton-coupled electron transfer, where protons are produced by an additional water dissociation step (H 2 O → H * + OH * ) [17][18][19] , which may result in large overpotentials and sluggish kinetics for limited NO 3 − RR performance (Fig. 1a).In contrast, direct nitrate reduction under strongly acidic conditions offers unique advantages compared with neutral/alkaline conditions.For example, the volatilization of NH 3 in neutral/alkaline electrolytes can be avoided, and ammonium fertilizers/salts (i.e., NH 4 NO 3 and (NH 4 ) 2 SO 4 ) can be obtained directly to be absorbed by the plants 20,21 .As the reaction becomes more acidic, abundant protons are provided for continuous hydrogenation reactions of NO 3 − , which may guarantee an enhanced NO 3 − conversion rate and generate NH 3 more energy-efficiently.All these considerations reveal the great potential of acidic NO 3 − RR for NH 3 production, which, however, is rarely explored now.
Hydrogen evolution reaction (HER) inevitably thus becomes a competitive reaction for NO 3 − RR in acidic media [22][23][24] .Up to now, most reported NO 3 − RR electrocatalysts working at pH≥ 7 are based on latetransition metals (such as Cu, Fe, Co, and Ni) 13,25,26 .Unfortunately, most of them are unstable in acid conditions and few are applied for acidic NO 3 − RR 27 .In addition, these electrocatalysts may suffer from the reduced NH 3 FE due to the obviously enhanced competitive HER in acidic media.Herein, we reported the application of Fe phthalocyanine/TiO 2 (FePc/TiO 2 ) as a stable and active electrocatalyst for energyefficient NO 3 high power density of 91.4 mW cm -2 for electricity supply and NH 3 synthesis, which can be applied for efficiently environmental sulfur recovery.Moreover, the Zn anode in the AAHZNB can be replaced by hydrazine (N 2 H 4 ) for additional N 2 H 4 pollutant removal in a N 2 H 4 -NO 3 fuel cell.

Results
TiO 2, with poor HER activity and notable corrosion resistance, is an appropriate and versatile electrocatalytic material for NO 3 − RR 28 .We first explored the NO 3 − RR performance of TiO 2 under acidic, neutral, and alkaline conditions.As shown in Fig. 1b, the linear sweep voltammetry (LSV) curve for NO 3 − RR in acidic media (pH 1) shows a much positive onset potential than that in neutral/alkaline media, and the current density in acid is always higher than that for neutral and alkaline media at the same potential.However, with potential being more negative, the current density for alkaline medium surpasses that for neutral medium due to the slow reaction kinetics in neutral medium, as evidenced by the more sluggish kinetics shown in Tafel slopes (Fig. 1c) and Nyquist plots (Supplementary Fig. 1 and Table 1).In addition, the Nyquist plot for acidic medium displays a lower ohmic resistance loss because of higher ionic conductivity than neutral medium 29 .Moreover, the activation energies (E a ) of TiO 2 for NO 3 -RR were calculated by studying the temperature-dependent reaction kinetics.Supplementary Fig. 2a-c shows the LSV curves in 0.5 M NO 3 with different pHs in the temperature range of 293 K to 303 K and E a values can be obtained by referring to the previous report 30 .When the potential is −0.25 V, the E a for pH 1 is 10.7 kJ mol −1 , much smaller than that for pH 7 and pH 13 (Supplementary Fig. 2d), suggesting a lower energy barrier for NO 3 − are detected by the UV-Vis spectrophotometer and the corresponding calibration curves are provided in Supplementary Figs.3-7.We calculated the NH 3 FE at different potentials in three media after electrolysis (Supplementary Fig. 8).At pH 1, TiO 2 shows high NH 3 FE (from 66% to 78.5%) at potentials in the range of -0.05 V and -0.55 V versus reversible hydrogen electrode (vs.RHE), as shown in Supplementary Fig. 9.However, NH 3 FE in neutral/alkaline media are very low (around 20%) at the first potential, increasing with the potential being more negative until -0.45 V.The highest NH 3 FE in acidic conditions is 78.5% at -0.25 V, while it is 74.3% at -0.45 V for neutral medium and 68.8% at -0.45 V for alkaline medium.The NH 3 partial current densities at different potentials and pH values of TiO 2 are shown in Fig. 1d.It is clear that TiO 2 consistently exhibits a higher NH 3 yield rate at pH 1 than that at pH 7 and pH 13 at the same applied potential, suggesting that acidic media enables a higher NH 3 yield.In order to investigate the pH-dependent influences on the reaction pathways, we also examined the evolution of free energy plots at pH values of 1, 7, and 13.Our analysis of the pH-dependent influences on free energies of reaction intermediates is elucidated through the role of H + .It becomes evident that NO 3 -RR exhibits favorable energetics when H + ions are readily available within an acidic medium.This trend is substantiated by the energy evolution diagram for NO 3 -RR (Supplementary Fig. 10).As the pH increases to 7 and 13, a concomitant increase in the free energies for NO 3 -RR is observed due to the sluggish kinetics of H + produced from additional water dissociation.The foregoing analysis further suggests that an acidic environment may be more conducive to NO 3 -RR for TiO 2 .All these results demonstrate that the acidic medium enables faster hydrogenation kinetics for NO 3 − RR and more energy-efficient NH 3 synthesis for TiO 2 compared to neutral and alkaline media.Apparently, the NH 3 FE of 78.5 % achieved with the TiO 2 catalyst in the acidic solution is still far from satisfactory and needs further improvement for practical use.Metallophthalocyanine dye is a common molecular catalyst for CO 2 reduction with poor HER performance and can operate stably under acidic conditions [31][32][33] .Fe plays an essential role in biological nitrite reductases to produce NH 3 through the photosynthetic nitrate assimilation pathway 34,35 .Fe phthalocyanine (FePc) is thus a promising NO 3 − RR catalyst.Through the simple wet chemical process, we prepared FePc/TiO 2 hybrid where Pc molecules are attached to TiO 2 surface via chemical bond and van der Waals forces.Scanning electron microscope (SEM) images of TiO 2 and FePc/ TiO 2 show the nanosheet structure (Supplementary Fig. 11).The mappings further reveal the uniform distribution of Ti, O, Fe, N and C within FePc/TiO 2 (Supplementary Fig. 12) and the energy dispersive X-ray spectroscopy (EDS) spectra suggest the co-existence of these elements with a weight percent of 0.73% for Fe element in FePc/TiO 2 (Supplementary Fig. 13).The X-ray diffraction (XRD) of FePc/TiO 2 shows similar peaks as TiO 2 due to the low content of FePc (Fig. 2a).Raman spectra of FePc/TiO 2 (Fig. 2b) shows typical signals for both FePc and TiO 2 36 , which is further verified by the FTIR measurement (Fig. 2c) 37 .A series of FePc/TiO 2 with different treatment time of 3, 6, and 9 h (donated as FePc/TiO 2 -x, x = 1, 2, and 3, respectively) are , as verified by the LSV curves in Fig. 2d, while the catalytic current density increases significantly with the presence of NO 3 − (Fig. 2e).Notably, FePc/TiO 2 -x shows an increased current density compared to TiO 2 and FePc/TiO 2 -2 displays the largest current density among the five samples.In contrast, FePc shows the lowest current density at fixed potentials.With the increased concentration of NO 3 − , the current density of FePc/TiO 2 -2 can be further improved (Fig. 2f).The NH 3 yield and corresponding FE at NO 3 − different concentrations of FePc/TiO 2 -2 were further obtained based on the established calibration curves for different NO 3 − electrolytes (Supplementary Fig. 15).The NH 3 formation rate of FePc/TiO 2 -2 shows an increased trend with the increased NO 3 − concentrations from 0.1 M to 0.5 M at all potentials (Supplementary Fig. 16a).When the NO 3 − concentration is up to 2 M, the NH 3 formation rate still significantly increases and reaches 22.5 mg h -1 cm -2 at -0.75 V. Besides, the NH 3 FE also shows similar increased trends with increased NO 3 − concentration at each potential (Supplementary Fig. 16b), suggesting that the high NO 3 − concentration fascinates the NH 3 formation.Specifically, the maximum NH 3 FE values for 0.1 M, 0.2 M, 0.3 M, 0.4 M, and 0.5 M NO 3 − electrolytes using FePc/TiO 2 -2 are determined as 77.0%, 79.2%, 83.2%, 87.9%, and 90.6%, respectively.The NH 3 FE in 2 M NO 3 − is 92.7%, close to that in 0.5 M NO 3 − electrolytes.Therefore, we chose 0.5 M for NO 3 − RR in the next explorations.After electrolysis at different potentials (Supplementary Fig. 17), we determined the concentration of production in the diluted electrolyte to calculate their FEs.The FePc/TiO 2 -2 shows a larger NH 3 yield rate and FE than those for TiO 2 at each potential (Fig. 2g, h).Additionally, the NH 3 yield (partial current density) of FePc/TiO 2 -2 steadily increases with the potential being more negative and reaches 17.4 mg h -1 cm -2 (219.7 mA cm −2 ) at -0.65 V (Supplementary Fig. 18).The FePc/TiO 2 -2 shows high NH 3 FE above 85% at -0.15 V to -0.55 V.It reaches the maximum value (90.6%) at -0.25 V and keeps at 68.7% even at -0.75 V.The NO 2 − byproduct was detected at the beginning on both FePc/TiO 2 -2 and TiO 2 catalysts electrodes, but the NO 2 − FEs showed a similar decreased trend with more negative potentials (Supplementary Fig. 19).Besides, the UV-Vis.adsorption curves of the electrolytes collected at different potentials are totally overlapped with that of blank standard solution (Supplementary Fig. 20), indicating that almost no hydrazine was formed during NO 3 − RR for both FePc/TiO 2 -2 and TiO 2 .Double layer capacitance (C dl ) of FePc/TiO 2 −2 is slightly larger than that of TiO 2 , indicative larger electrochemical active surface area on FePc/TiO 2 −2 for efficient catalysis (Supplementary Fig. 21) 38 .The FePc is active for NO 3 -RR but only delivers the maximum NH 3 FE of 76.0% at −0.45 V (Supplementary Fig. 22).The mass activity of FePc/TiO 2 with different FePc loading masses were also studied.FePc/TiO 2 -2 shows a higher geometrical area and mass normalized NH 3 yield than FePc/TiO 2 -1 and FePc/TiO 2 -3 (Supplementary Fig. 23a, b), revealing that higher or lower FePc mass loading would lead to the decreased NH 3 yield.Besides, it shows similar peak FE values for NH 3 formation with 88.7%, 90.6%, and 87.4% for FePc/TiO 2 -1, FePc/TiO 2 -2, and FePc/TiO 2 -3 (Supplementary Fig. 23c), respectively, suggesting that the catalyst loading shows limited impact on the NH 3 FE of NO 3 − RR.All these results demonstrate the enhanced electrochemical NO 3 − RR performance of FePc/TiO 2 −2.As far as we know, the FePc/ TiO 2 −2 exhibits higher NH 3 yield than most reported TiO 2 -based catalysts, as shown in Fig. 2i and Supplementary Table 2. Though there is still a gap in performance between FePc/TiO 2 −2 and the state-of-theart NO 3 − RR electrocatalysts performed in alkaline media with high NO 3 − concentrations up to 1 M, it can be confirmed that the preciousmetal-free FePc/TiO 2 −2 shows higher NH 3 synthesis performance than RuCu 39 and Fe 2 M-trinuclear-cluster metal-organic frameworks 40 catalysts recently reported in acid.
To determine the nitrogen source in the conversion of NO 3 --to-NH 3 and the amount of produced NH 3 , we employed 15 NO 3 -and 14 NO 3 as the feedstock and detected the NH 3 by 1 H nuclear magnetic resonance (NMR) method.We first built the calibration curve using the standard ( 14 NH 4 ) 2 SO 4 and ( 15 NH 4 ) 2 SO 4 , as displayed in (Supplementary Fig. 24).Then, we conducted the electrolysis at -0.45 V for 0.5 M 15 NO 3 and 14 NO 3 -electrolytes, respectively.The electrolytes were collected for further analysis.Typical double and triple peaks appear in NMR spectra for 15  , respectively (Fig. 3a).Additionally, the NH 3 yield rate and FE at -0.45 V obtained from the NMR method are finally recorded at 11.2 mg h -1 cm -2 and 85.0% with 14 NO 3 -and at 11.8 mg h -1 cm -2 and 88.7% with 15 NO 3 -, which are close to the UV-Vis.results (Fig. 3b), indicative of the reliability of the experimental data for NH 3 determination.Meanwhile, the maximum NH 3 FE at -0.25 V maintains a stable value with prolonged reaction time (Fig. 3c).To investigate the long-term stability, we extended the electrolysis of FePc/TiO 2 -2 to a duration of ~24 hours in 60-mL electrolyte of 0.5 M NO 3 − (pH 1).The current density exhibits a slight decrease during the initial two hours, followed by a sustained and nearly constant trend in the subsequent time period (Supplementary Fig. 25).The NH 3 FE recorded at different times remains almost stable and only decreases slightly in the final 6 hours from 86.6% to 81.9%.These results indicate the good electrochemical stability of FePc/TiO 2 .Furthermore, the post-test FePc/TiO 2 -2 is thoroughly characterized.SEM image confirms the intact nanosheet structure (Supplementary Fig. 26).XRD patterns of FePc/TiO 2 −2 after electrolysis at different potentials show nearly the same diffraction peaks as the original one (Fig. 3d), indicating the good structure stability of FePc/TiO 2 −2.EDS mappings and FTIR analyses reveal the presence of FePc in the tested electrode (Supplementary Fig. 27).We also collected the XPS spectra of FePc/TiO 2 −2 after electrolysis for 1 h at different potentials for comparison.As shown in Fig. 3e, with the potential being more negative, the typical peaks for Ti 4+ in Ti 2p region slightly shift toward smaller binding energies, indicating more Ti x+ with a low valence state may generate during the NO 3 − RR 41 .In the N 1 s spectra, a new peak around 408.5 eV assigned to absorbed NO 3 − and the peak around 397 eV assigned to the surface NH 3 species are observed during the electrolysis (Fig. 3f) 42,43 .However, with the potential being more negative, the peak assigned to Fe-N in FePc becomes weaker 44 .To investigate whether the catalyst dissolved in the solution, we conducted inductively coupled plasma-mass spectrometry (ICP-MS) measurement to the solution after electrolysis.Only 5.17 wt% of Fe dissolved in the first 4 hours, and this figure increases to about 20 wt% after 24-hour electrolysis (Supplementary Fig. 28).It should be noted that Ti element is also detected in the solution, suggesting the inevitably partial dissolution of the overall FePc/TiO 2 −2 electrode in the acidic conditions after long-term electrolysis, which may be associated with the slight loss of electrocatalytic NO 3 − RR activity.
To identify the NO 3 − absorbed on Fe site, FePc/TiO 2 −2 was immersed in the electrolyte solution for 24 hours, and then collected the XPS spectra before and after immersion for further analysis.The typical peak for NO 3 − appears in the spectra of FePc/TiO 2 −2 after immersion, and the peak for Fe 2p 3/2 region shifts toward higher binding energy compared to that before the immersion (Supplementary Fig. 29), indicating the possible interaction between NO 3 and Fe centers after adsorption.To further elucidate the role of the active site of FePc/TiO 2 in NO 3 − RR, we first conducted SCN -intoxication experiments to block Fe species of FePc/TiO 2 −2 because of the strong affinity of SCN -with Fe species 45,46 .It was found that the NO 3 (Fig. 3g, h).The characteristic peak at 1634 cm -1 is attributed to the bending vibration of the adsorbed water involved in the NO 3 − RR in the solution of the thin layer or the NO intermediate due to the overlap of peaks 47 .The band at 1537 cm −1 could be assigned to NH 2 bending, while the band at 1515 cm −1 is ascribed to the vibration peak of NO 48,49 .Meanwhile, the absorption bands centered at 1243 cm −1 are assigned to symmetric and antisymmetric stretching vibration of the NO 2 group.The bands around 1150 cm −1 and 1100 cm −1 are attributed to the H-N stretching vibration of hydroxylamine (NH 2 OH) and produced NH 3 50 , respectively.Similar peaks were also observed on FePc (Supplementary Fig. 31).These observation reveals the possible NO 3  32).Conversely, the remaining portion of the FePc primarily exhibits van der Waals interactions with the TiO 2 substrate.Further analysis, involving charge density difference assessments and density of states examinations, substantiates a considerable charge transfer (0.12 e − ) and robust Fe-O 3d-2p orbital overlap below the Fermi level between FePc and TiO 2 (Supplementary Fig. 33), thus confirming a genuine chemical interaction rather than merely van der Waals interactions.To assess the stability of the Fe−O chemical bond during NO 3 − reduction, we performed relative energy calculations, which can quantifiably measure the interactions between FePc and TiO 2 .Our findings reveal an interaction energy of −2.55 eV between FePc and TiO 2, with this value remaining consistently close to −2.5 eV even after the adsorption of intermediate species on the Fe site (Supplementary Fig. 34).This consistency demonstrates the enduring − is preferably adsorbed on the Fe site with a larger adsorption energy of 1.48 eV compared to Ti (Supplementary Fig. 35), implying that Fe is more likely to be the active site for NO 3 − RR.Charge density difference analysis reveals significant charge transfer between NO 3 − and the Fe site, as depicted in Fig. 4a.This is further corroborated by the density of states analysis, which demonstrates strong d-p orbital overlap at a more negative energy level below the Fermi level for Fe-NO 3 compared to Ti-NO 3 (Fig. 4b), indicating a more robust covalent bond component in the Fe-NO 3 .Figure 4c shows the thermodynamics of the NO 3 − reduction reaction on TiO 2 and FePc/TiO 2 surfaces.Supplementary Figs.36 and 37 display the adsorption configuration of different N-containing intermediates.From the Gibbs free energy profile, it is clear that the rate-limiting step for NO 3 − reduction on the FePc/TiO 2 surface is the formation of the NOH* intermediate, which requires an energy input of 0.74 eV.FePc also exhibits the reduction of *NO to *NOH is the rate-determining step with an energy barrier of 0.81 eV (Supplementary Fig. 38a, b).It means that NO is an important reaction intermediate, which agrees with our in-situ FTIR spectra observations.In contrast, for the pristine TiO 2 system, the reactiondetermining step is NH 3 desorption, which requires at least 1.29 eV of energy input.Overall, the FePc/TiO 2 composite exhibits higher catalytic activity for reducing NO 3 − than pristine TiO 2 and FePc.Remarkably, the FePc/TiO 2 catalyst shows inert activity towards HER, a side reaction with a reaction-free energy of 0.42 eV (Fig. 4d), demonstrating the superior HER resistance.Conversely, the reaction free energy of HER on pristine TiO 2 and FePc is -0.06 and 0.38 eV (Supplementary Fig. 38c), respectively.
The development of NO x − -based electrochemical battery systems holds great promise in sustainable development since it can produce high value-added NH 3 and meanwhile generate electricity [51][52][53][54][55] .Thanks to the high theoretical capacity and low redox potential of Zn metal [56][57][58] , aqueous Zn-NO 3 − batteries have emerged as such an ideal system.Zhi's group first developed galvanic Zn-NO 3 − cell with an OCV of 0.81 V and a power density of 0.87 mW cm −2 , based on a Pd/TiO 2 supported on carbon cloth as the cathode 19 .Subsequently, they demonstrated that such Zn-NO 3 − battery with OCV of 1.22 V can be rechargeable but irreversible and cathodic water oxidation occurs during the charging process 9 .Interestingly, Jiang et al. recently proposed a rechargeable and reversible Zn-nitrogen flow batteries and NH 3 can be oxidized to NO 2 − and further NO 3 − during charging process.However, it lost the unique advantage of turning waste into treasure and such battery only exhibits an OCV of 1.39 V and a power density of 10.0 mW cm −2 52 .Up to now, the highest power density of Zn-NO 3 − Zhou's group reports battery 59 .Benefiting from the high NO 3 − RR activity, the galvanic Zn-NO 3 − battery with OCV of 0.94 V exhibits a power density as high as 70.7 mW cm −2 with CuNi nanoparticles supported on Cu foil as the cathode and 3.5 M NaOH/0.71M NO 3 − catholyte.However, all reported Zn-NO 3 − batteries deliver limited voltages and the power density and NH 3 yield/selectivity are still desired for this electrochemical cell system, which severely depends on the conditions of the cathodic part.For a Zn-NO 3 − battery, a more positive potential and a higher catalytic current for acidic NO 3 -RR at the cathode generally contribute to a higher output power density.Compared to the reported Zn-NO 3 − batteries equipped with NO 3 − RR in neutral/alkaline conditions, an alkaline-acidic hybrid Zn-NO 3 − battery (AAHZNB) is highly attractive to offer a large power density with high NH 3 yield.
Inspired by the above considerations, we assembled such an AAHZNB battery with FePc/TiO 2 -2 as the cathode (in the acidic electrolyte) and Zn plate (in the alkaline electrolyte) as an anode.A bipolar membrane is used to separate the cathodic and anodic chambers (Fig. 5a).The Zn-NO 3 − battery delivers a stable OCV of 1.99 V (Fig. 5b), higher all reported values of Zn-NO 3 − batteries up to now (Supplementary Table 3).The high OCV is ascribed to the intrinsic potential difference of Zn oxidation and NO 3 − RR as well as the pH difference between the two chambers separated by a bipolar membrane, which can efficiently avoid the direct neutralization of acid and alkali.Supplementary Fig. 39 shows LSV curves of anodic oxidation reaction of Zn plate and the cathodic NO 3 − RR using FePc/TiO 2 in different media at potentials versus Ag/AgCl reference electrode.It is clear that the acidic NO 3 − RR shows a larger potential gap than that for neutral and alkaline media.NH 3 product formed in the cathodic compartment was identified after discharging at different voltages (Supplementary Fig. 40).AAHZNB during the discharge process achieves a peak FE of 88.2% at 0.7 V and a high NH 3 yield of 12.3 mg h -1 cm -2 at 0.4 V (Fig. 5c).Importantly, AAHZNB exhibits an exceptional peak power density of 91.4 mW cm −2 (Fig. 5d).We also collected the LSV curve flow Zn-NO 3 battery.It is found that the flow Zn-NO 3 -battery shows a peak power density of 93.55 mW cm -2 , which is very close to that obtained from a static mode with stirring (Supplementary Fig. 41).The rate performance of the AAHZNB was also tested.Figure 5e shows the laddershaped discharging curves at different current densities and each step exhibits stable discharging plateaus.After discharging at a current density up to 50 mA cm −2 , the voltages are well recovered at current densities of 40, 30, and 20 mA cm -2 , indicating the high stability of AAHZNB.Supplementary Figure 42 shows the chronopotentiometry curves and the NH 3 FE at different times.The acid-base hybrid Zn-NO 3 − battery shows slightly decreased current density at the first 2 h at 0.9 V and maintains stability in the next 8 h.Besides, the NH 3 FE of the cathode changes from the initial 84.7% to 81.8% after 10-h electrolysis.As such, we can conclude that AAHZNB employed by the FePc/TiO 2 -2 could achieve electricity output with the maximum power density of 91.4 mW cm −2 and NH 3 production rate of 12.3 mg h -1 cm -2 , which are highest among the Zn-NO x − batteries reported so far (Fig. 5f).Besides, it even surpasses some of the reported Zn-H 2 O batteries, solid-state Zn-air batteries (ZAB), direct urea fuel cells (DUFCs), direct hydrazine fuel cells (DHzFCs), direct formic acid fuel cells (DUFCs), as summarized in Supplementary Table 4.
The high performance of FePc/TiO 2 -2 for acidic NO 3

−
RR and AAHZNB provides more opportunities for the practical applications.One of the possible applications is the environmental sulfur recovery driven by high power density of AAHZNB.H 2 S/S 2− are common pollutants in the exhaust gas and sewage of industry.Electrochemical oxidation of S 2− or the H 2 S splitting as valuable sulfur species can be combined with cathodic hydrogen evolution, which holds great significance environmentally and economically 60 .One step further, the hydrazine (N 2 H 4 ) can be employed to replace Zn anodes in the nitratebased battery due to its low oxidation potential 61 , realizing a fuel cell treating both pollutes and producing electricity simultaneously.Figure 6a shows the picture of an electrolyser composed of a cathodic hydrogen evolution and anodic sulfur oxidation reaction (SOR) with commercial Pt/C as bifunctional catalysts successfully powered by the AAHZNB with the current density 35.6 mA cm -2 .With electrolysis going, a gradual rise of UV-Vis absorption bands at 300 nm is observed, indicating the generation of short-chain S 2 2− in the anolyte during electrolysis (Fig. 6b) 60 .The oxidation product can be efficiently obtained through the acid treatment of the electrolyte and XRD pattern for the collected yellow powder corresponds to the elemental sulfur (Supplementary Fig. 43). Figure 6c shows the schematic diagram of the proposed N 2 H 4 -NO 3 − fuel cell with FePc/TiO 2 -2 as the cathode.We used commercial Pt/C as an anodic catalyst and found that the onset potential is about -1 V vs. Ag/AgCl and the current density reaches saturation in 1 M KOH + 0.3 M N 2 H 4 (Fig. 6d).The onset potential for HzOR is negative than that for NO 3 − RR, indicating that the N 2 H 4 -NO 3 − fuel cell is workable.The assembled N 2 H 4 -NO 3 -fuel cell shows a discharge voltage of 0.75 V at 1 mA cm −2 and a peak power density of 11.5 mW cm −2 (Fig. 6e).The NH 3 FE keeps at around 80% when discharged at different voltages (Fig. 6f and Supplementary Fig. 44).All these studies unveil the practical applicability of NO 3 -based fuel cells with great energy and environmental significance and further introduce NO 3 -as a potential member in fuel cell systems.

Discussion
Thanks to the advantages of abundant protons supply and fast kinetics of NO 3 -RR in acidic conditions, we have successfully reported the high-efficiency NH 3 electrosynthesis using the FePc/ TiO 2 nanosheet.Such catalyst delivers an NH 3 yield rate of 17.4 mg h -1 cm -2 and a FE of 90.6% for acidic NO 3 --to-NH 3 conversion at pH 1.The introduction of FePc strengthens the adsorption of the N-containing intermediate and reduces the energy barrier of the rate-determining step, thus promoting the NO 3 -RR performance of TiO 2 .Furthermore, the alkaline-acidic hybrid Zn-NO 3 − battery was developed for simultaneous NH 3 and electricity generation with a high open-circuit voltage of 1.99 V and an impressive power density of 91.4 mW cm -2 , which can be applied in the environmental sulfur recovery.Moreover, the developed all-pollute N 2 H 4 -NO 3 -fuel cell can simultaneously eliminate N 2 H 4 /NO 3 -and supply electricity.This work not only demonstrates the attractive potential of acidic

Characterization
The crystalline, morphologies and microstructures of samples were investigated by XRD using a Bruker D2 Phaser diffractometer with Cu Kα irradiation (λ = 1.54 Å) and field-emission scanning electron microscopy (FEI Quanta 450 FEG).The surficial chemical states and compositions of the as-obtained products were investigated by XPS (ESCALB 250) with an Al Kα X-ray beam (E = 1486.6eV).The C 1s peak with the binding energy of 284.8 eV was used as the calibration standard. 1H-NMR measurements were performed on Bruker 400 MHz ASCEND AVANCE III HD Nuclear Magnetic Resonance System (NMR-400).UV-Vis spectroscopy measurements were carried out using a Dynamica Halo DB−20S UV-Vis Spectrophotometer.FTIR measurements were carried out using Spectrum Two FTIR Spectrometers by PerkinElmer.Raman spectroscopy was performed on a WITec alpha300 Raman System under excitation of 632.8 nm laser light.ICP-MS was performed on Agilent 5110.

Electrochemical measurements
The electrochemical NO 3 − RR measurements were performed in a taditional H-type cell with a CHI 760E electrochemical workstation (Chenhua, China) using a three-electrode system.TiO 2 and FePc/TiO 2 -x supported on Ti mesh (0.5 × 0.5 cm 2 ), Ag/AgCl (saturated KCl aqueous solution), and Pt foil (1.5 × 1.5 cm 2 ) electrode were served as working electrode (WE), reference electrode (RE), and counter electrode (CE), respectively The cathodic and anodic chambers are separated by a RR is 0.1 M HNO 3 /0.4M KNO 3 (pH is about 1), while the electrolyte for HER is 0.1 M HClO 4 (pH 1).The electrolytes for neutral and alkaline NO 3 − RR are 0.1 M K 2 SO 4 /0.5 M KNO 3 (pH 7) and 0.1 M KOH/0.5 M KNO 3 (pH 13), respectively.The pH of the solution was determined when the displayed value was stable using a pH meter (PHS-3C, Leici).The electrochemical measurements were performed in the Ar atmosphere with a gas flow rate of 20 sccm and they were kept stirring (600 rpm) throughout the tests to minimize the mass transfer limitation.LSV tests were conducted with a scan rate of 5 mV s −1 .The chronoamperometry tests were performed in a typical H-type cell that contains 15-mL electrolyte for each chamber.The electrochemical impedance spectroscopy was obtained in the frequency range from 0.1 Hz to 100 kHz upon an AC voltage amplitude of 5 mV at an opencircuit potential and room conditions.All the final reference potential was converted to the reversible hydrogen electrode (RHE) using the Nernst equation: E(RHE) = E(Ag/AgCl) + 0.197 + 0.059 × pH.To prepare the Pt/C loaded electrode to catalyze SOR and HzOR, Pt/C (10 mg) and Nafion solution (50 μL 5 wt%) were dispersed in water/ethanol solvent mixture (1 mL, 1:1 v/v) by 30 min sonication to form an ink.Then catalyst ink (100 μL) was loaded on a carbon cloth (1 × 1 cm 2 ) with mass loading of 1 mg cm −2 .

Assembly of batteries and electrochemical test
For Zn-NO 3 -battery, the FePc/TiO 2 -2 (1 cm 2 ) and Zn plate (4 cm 2 , thickness = 0.2 mm) were used as the cathode and anode for Zn-NO 3 -battery, respectively.The distance of both electrodes is 4 mm.15-mL catholyte (0.1 M HNO 3 + 0.4 M KNO 3 ) and 15-mL anolyte (6 M KOH) were separated by a bipolar membrane (fumasep FBM, 4 cm 2 ).The discharge polarization curves with a scan rate of 10 mV s -1 were collected using a CHI 760E workstation under room conditions with vigorous stirring (600 rpm).After electrolysis at different voltages for 30 min, the electrolyte solution was collected and diluted for the subsequent detection.The power density (P) of the Zn-NO 3 -battery was the product of voltage and discharge current density.For the flow mode of Zn-NO 3 -battery, the electrolyte in the cathode and anode was circulated by a peristaltic pump (Kamoer, F01A-STP) with a flow rate of 25 mL min −1 .The assemble of N 2 H 4 -NO 3 -fuel cell follows the similar procedure except the anode is replaced by Pt/C electrode and the anodic electrolyte is 1 M KOH + 0.3 M N 2 H 4 .

RR
To extract the E a for the NO 3 − RR, the LSV curves were first collected in a 0.5 M NO 3 − solution at different pH values and at different temperatures.Then, E a can be determined according to the Arenius equation: j = Aexp (−E a /RT), where j is the current density, A is the apparent preexponential factor, R is the ideal gas constant and T is the temperature.

Determination of NH 3
The quantity of generated NH 3 was assessed utilizing the indophenol blue method 55 .All data was recorded three times to obtain the error bar.Subsequent to the NO 3 − RR test, a 1-mL aliquot of diluted electrolyte was extracted, neutralized, and subjected to further analysis.A solution comprising 0.625 M NaOH, 0.36 M salicylic acid, and 0.17 M sodium citrate (1.25 mL) was added to the neutralized electrolyte.Following this, 150 μL of sodium nitroferricyanide solution (10 mg mL −1 ) and 75 μL of NaClO (available chlorine 4.0 wt%) solution were introduced.Following a 2-hour incubation period under ambient conditions, the UV-Vis absorption spectrum was recorded, and the absorbance value at 658 nm was determined.A concentrationabsorbance calibration curve was established using a series of known standard concentrations of (NH 4 ) 2 SO 4 solution dissolved in the electrolyte.

−
In all, 0.1 mL of mixture including 2 M HCl and 10 mg mL −1 sulfanilamide and 5 mL diluted liquid products were first mixed.Then, 0.1 mL N-(1-Naphthyl) ethylenediamine dihydrochloride solution (10 mg mL −1 ) was added to above mixed solution.The acquired solution was rested for 30 min under ambient conditions.Finally, the absorbance at the wavelength of 540 nm was recorded.The concentration-absorbance calibration curve was plotted using a series of concentrations known as standard KNO 2 solution dissolved in the electrolyte.

Determination of N 2 H 4
The presence of N 2 H 4 in the electrolytes was determined utilizing the Watt-Chrisp method 55 .A color reagent was prepared by combining 100 mL ethanol, 2 g para(dimethylamino) benzaldehyde, and 12 mL concentrated HCl.Subsequently, 2 mL of the color reagent was introduced into 2 mL of the electrolyte.Following a 30-minute incubation period, the absorbance at the wavelength of 458 nm was recorded.A concentration-absorbance calibration curve was then constructed using a series of known standard N 2 H 4 solution dissolved in the electrolyte.

Isotope labeling experiments
A 0.5 M solution of K 15 NO 3 (pH 1) served as the electrolyte in the cathode compartment.To facilitate quantitative determination, a certain amount of maleic acid (C 4 H 4 O 4 ) was dissoved in electrolyte solution with a concentration of 400 ppm.Subsequently, 50 μL of deuterium oxide (D 2 O) was added to 0.5 mL of the aforementioned mixture for 1 H NMR (400 MHz) detection 55 .NH 3 detection via NMR was also conducted in an electrolyte consisting of 0.1 M H 14 NO 3 /0.4M K 14 NO 3 .The subsequent steps followed the previously outlined procedure.The peak area ratio of NH

In-situ FTIR test
In-situ FTIR spectroscopy experiments were conducted using a modified electrochemical cell (see Supplementary Fig. 45) integrated into a Nicolet 6700 FTIR spectrometer equipped with a mercury-cadmiumtelluride (MCT) detector cooled by liquid nitrogen.The working electrode, counter electrode, and reference electrode utilized were the self-supported catalysts electrode, Pt wire, and a Ag/AgCl electrode, respectively.Each spectrum was acquired with a time resolution of 30 seconds.Prior to the test, the initial state with an open circuit was scanned for background correction., and N 2 H 4 were determined using the following equations 55 : Yield rate ðNO 2 À Þ = ðC × V × nÞ=ðt × AÞ ð 4Þ Where F represents the Faraday constant (96485 C mol −1 ), C denotes the measured concentration of NH 3 , V signifies the volume of the electrolyte, Q represents the total charge passed through the electrode, n stands for the dilution factor, and A signifies the geometric area of the working electrode (0.5 × 0.5 cm²).

Computational details
Vienna Ab initio Simulation Package (VASP) was used to conduct spinpolarized density functional theory (DFT) calculations.The Perdew-Burke-Ernzerhof (PBE) functional was utilized for exchangecorrelation treatment using the Generalized Gradient Approximation (GGA).The projector-augmented wave (PAW) method was employed to describe the core electrons, and the valence electronic states were expanded in plane-wave basis sets.Dispersion interactions were treated using the DFT-D3 method with Becke-Johnson (BJ) damping.A cutoff energy of 450 eV was set, and the force convergence criterion was set to 0.05 eV/Å.The optimization of the anatase-TiO 2 (101) surface was carried out using a (3x3x1) k-point, while a Gamma point was adopted for the TiO 2 /FePc surface optimization.

− 3 −
RR in acid (pH = 1) with impressive NH 3 yield rate of 17.4 mg h -1 cm -2 and a NH 3 FE of 90.6%.Such FePc/TiO 2 exhibits poor HER activity and enhanced NO 3 − adsorption, fascinating the selective NO RR to NH 3 .In-situ Fourier transform infrared spectroscopy (FTIR) and theoretical calculation reveals the reaction pathway over FePc/ TiO 2 with *NO → *NOH as rate-determining step.The developed alkaline-acid hybrid Zn-NO 3 -battery (AAHZNB) based on FePc/TiO 2 cathode shows a high open-circuit voltage (OCV) up to 1.99 V with a

-−
RR in acidic media.All the liquid products of NO 3 RR such as NH 3 , N 2 H 4 and NO 2

Fig. 1 |−
Fig. 1 | Acidic media enables higher kinetics for NO 3 − RR of TiO 2 .a Pathways for *H production in NO 3 − RR process under different conditions.The acidic conditions offer abundant protons for continuous hydrogenation reactions of NO 3 − .b LSV curves and (c) Tafel curves of TiO 2 nanosheet for NO 3 − RR with 0.5 NO 3 − in the

−
RR pathway as follows: NO3 − → *NO 3 → *NO 2 → *NO → *NOH → *NH 2 OH → *NH 3 .Density functional theory calculations were carried out to gain insight into the NO 3 − reduction reaction on TiO 2 and FePc/TiO 2 systems.It was discovered that the FePc molecule prefers to lie on the surface of TiO 2 with its basal plane parallel to the TiO 2 (101) surface.A clear chemical bond (~2.28 Å in length) is formed between the Fe site and the lattice oxygen on the TiO 2 surface within the FePc/TiO 2 composite (Supplementary Fig.

Fig. 3 |---
Fig. 3 | Analysis of the FePc/TiO 2 during NO 3 -RR electrolysis.a 1 H NMR spectra of the electrolytes after the measurements and the referenced spectrum of ( 15 NH 4 ) 2 SO 4 .b The NH 3 yield rate and FE of FePc/TiO 2 −2 at −0.45 V measured by NMR and UV-Vis methods for a quantitative comparison.c The NH 3 FE of FePc/ TiO 2 -2 after electrolysis at various time at −0.25 V in acidic conditions.d The XRD patterns, (e) XPS spectra in Ti 2p region and (f) XPS spectra in N 1 s region of FePc/ TiO 2 -2 before and after electrolysis at different potentials.g In-situ FTIR spectra of FePc/TiO 2 -2 working at different potential for NO 3 -RR.h The 2D FTIR contour map of FePc/TiO 2 -2 for NO 3 -

Fig. 5 |
Fig. 5 | High voltage Zn-NO 3 − batteries for simultaneous NO 3 − conversion to NH 3 and electricity supply.a The schematic diagram of the AAHZNB with FePc/ TiO 2 -2 as cathode and Zn foil as anode.b The OCV of the AAHZNB.c The NH 3 yield and FE after discharge at different voltages of the AAHZNB.Error bars are determined from three replicate trials at different voltages.d The discharge curve of AAHZNB and the corresponding power density.e The multi-step chronoamperometric curve of the AAHZNB for discharging at different current densities.f Comparison of power density between the AAHZNB and the reported Zn-NO 3 − batteries (CV is cyclic voltammetry, NF is nickel foam, DM is dense membranous, SAA is single atom alloy, MP is metastable phase and SAC is single atom catalyst).

Fig. 6 |−
Fig. 6 | AAHZNB for environmental sulfur recovery and N 2 H 4 -NO 3 − fuel cell for electricity generation and NH 3 synthesis.a The picture of the AAHZNB to power anodic SOR and cathodic HER.b The UV-Vis.adsorption curves for diluted electrolyte after the sulfur oxidation reaction driven by the AAHZNB for different time.c The schematic diagram of proposed N 2 H 4 -NO 3 − fuel cell with FePc/TiO 2 -2 as the cathode.

FE and yield rate for NO 3 −
RRFEs and area-normalized yield rates of NH 3 , NO 2 − 4 + to C 4 H 4 O 4 was recorded, and the concentration was determined based on standard calibration curves.These calibration curves were established by collecting peak area ratios of NH 4 + at various concentrations of 14 NH 4 + and C 4 H 4 O 4 .