A Zinc-Air Battery based Desalination Device.

Efficiently storing electricity generated from renewable resources and desalinating brackish water are both critical for realizing a sustainable society. Previously reported desalination batteries need to work in alternate desalination/salination modes and also require external energy inputs during desalination. Here, we demonstrate a novel zinc-air battery-based desalination device (ZADB), which can desalinate brackish water and supply energy simultaneously. The ZABD consists of a zinc anode with a flowing ZnCl2 anolyte stream, a brackish water stream, and an air cathode with a flowing NaCl catholyte stream, separated by an anion exchange membrane and a cation exchange membrane, respectively. During the discharging, ions in brackish water move to the anolyte and catholyte and return to the feed steam during charging. The ZABD can desalt brackish water from 3000 ppm to the drinking water level at 120.1 ppm in one step and concurrently provide an energy output up to 80.1 kJ mol-1 under the discharge current density of 0.25 mA cm-2. Further, the ZABD can be charged/discharged over 20 cycles without significant performance deterioration, demonstrating its reversibility. Moreover, the desalination performances can be adjusted by varying current densities and are also influenced by the initial concentration of salt feeds. Besides, two ZABD devices were connected in series to drive 60 light-emitting diodes during the salt removal process without external power supply over 2000 min. Overall, this ZABD system demonstrates the potentials for simultaneous water desalination and energy supply, which is suitable for many urgent situations.

[1]  V. Presser,et al.  High-performance ion removal via zinc–air desalination , 2020 .

[2]  S. Liao,et al.  Emerging applications of atomic layer deposition for lithium-sulfur and sodium-sulfur batteries , 2020 .

[3]  Li Wei,et al.  Flexible Rechargeable Zinc-Air Battery with Excellent Low-Temperature Adaptability. , 2020, Angewandte Chemie.

[4]  R. Eichel,et al.  Influence of Al Alloying on the Electrochemical Behavior of Zn Electrodes for Zn–Air Batteries With Neutral Sodium Chloride Electrolyte , 2019, Front. Chem..

[5]  A. Mahmood,et al.  Flexible Zinc-Ion Hybrid Fiber Capacitors with Ultrahigh Energy Density and Long Cycling Life for Wearable Electronics. , 2019, Small.

[6]  Qiang Ru,et al.  An organic flow desalination battery , 2019, Energy Storage Materials.

[7]  Nelson Arias Ávila,et al.  Renewable Energies , 2019, Culture and Environment.

[8]  B. L. Mehdi,et al.  High Electrochemical Seawater Desalination Performance Enabled by an Iodide Redox Electrolyte Paired with a Sodium Superionic Conductor , 2019, ACS Sustainable Chemistry & Engineering.

[9]  Volker Presser,et al.  Redox-electrolytes for non-flow electrochemical energy storage: A critical review and best practice , 2019, Progress in Materials Science.

[10]  Xiaozhou Liao,et al.  Cobalt Nanoparticles Confined in Carbon Cages Derived from Zeolitic Imidazolate Frameworks as Efficient Oxygen Electrocatalysts for Zinc‐Air Batteries , 2019, Batteries & Supercaps.

[11]  Di He,et al.  Analysis of capacitive and electrodialytic contributions to water desalination by flow-electrode CDI. , 2018, Water research.

[12]  Qiang Ru,et al.  Coupling desalination and energy storage with redox flow electrodes. , 2018, Nanoscale.

[13]  Yongyao Xia,et al.  Integrating Desalination and Energy Storage using a Saltwater-based Hybrid Sodium-ion Supercapacitor. , 2018, ChemSusChem.

[14]  Kyle C. Smith,et al.  Quantifying the Trade-offs between Energy Consumption and Salt Removal Rate in Membrane-free Cation Intercalation Desalination , 2018, 1802.06828.

[15]  Chao Zhang,et al.  Energy storage system: Current studies on batteries and power condition system , 2018 .

[16]  Yu Fu,et al.  Highly Stable Hybrid Capacitive Deionization with a MnO2 Anode and a Positively Charged Cathode , 2018 .

[17]  S. Sahu,et al.  Electrochemical Desalination of Seawater and Hypersaline Brines with Coupled Electricity Storage , 2018 .

[18]  Fuming Chen,et al.  Dual-ions electrochemical deionization: a desalination generator , 2017 .

[19]  Bruce E. Logan,et al.  Low Energy Desalination Using Battery Electrode Deionization , 2017 .

[20]  Volker Presser,et al.  Faradaic deionization of brackish and sea water via pseudocapacitive cation and anion intercalation into few-layered molybdenum disulfide , 2017 .

[21]  Meng Ding,et al.  A dual-ion electrochemistry deionization system based on AgCl-Na0.44MnO2 electrodes. , 2017, Nanoscale.

[22]  Xiao Xiao,et al.  Rechargeable zinc–air batteries: a promising way to green energy , 2017 .

[23]  Jeyong Yoon,et al.  Rocking Chair Desalination Battery Based on Prussian Blue Electrodes , 2017, ACS omega.

[24]  Kyle C. Smith,et al.  Nickel Hexacyanoferrate Electrodes for Continuous Cation Intercalation Desalination of Brackish Water , 2016, 1612.08293.

[25]  Alex Rozhin,et al.  Zinc regeneration in rechargeable zinc-air fuel cells—A review , 2016 .

[26]  Guihua Yu,et al.  A Bio-Inspired, Heavy-Metal-Free, Dual-Electrolyte Liquid Battery towards Sustainable Energy Storage. , 2016, Angewandte Chemie.

[27]  M. Hosseini,et al.  Electrocatalytical study of carbon supported Pt, Ru and bimetallic Pt-Ru nanoparticles for oxygen reduction reaction in alkaline media , 2015 .

[28]  Volker Presser,et al.  Water desalination via capacitive deionization : What is it and what can we expect from it? , 2015 .

[29]  Hongjie Dai,et al.  Recent advances in zinc-air batteries. , 2014, Chemical Society reviews.

[30]  G. Urban,et al.  Electrochemical characteristics of nanostructured platinum electrodes--a cyclic voltammetry study. , 2014, Physical chemistry chemical physics : PCCP.

[31]  Andreas Poullikkas,et al.  A comparative overview of large-scale battery systems for electricity storage , 2013 .

[32]  Guosong Hong,et al.  Advanced zinc-air batteries based on high-performance hybrid electrocatalysts , 2013, Nature Communications.

[33]  Jesús Palma,et al.  New testing procedures of a capacitive deionization reactor. , 2013, Physical chemistry chemical physics : PCCP.

[34]  Hui-Ming Wee,et al.  Renewable energy supply chains, performance, application barriers, and strategies for further development , 2012 .

[35]  Andreas Sumper,et al.  A review of energy storage technologies for wind power applications , 2012 .

[36]  Yi Cui,et al.  A desalination battery. , 2012, Nano letters.

[37]  G. Soloveichik Battery technologies for large-scale stationary energy storage. , 2011, Annual review of chemical and biomolecular engineering.

[38]  G. Graff,et al.  A Stable Vanadium Redox‐Flow Battery with High Energy Density for Large‐Scale Energy Storage , 2011 .

[39]  Jun Liu,et al.  Electrochemical energy storage for green grid. , 2011, Chemical reviews.

[40]  Youngsik Kim,et al.  Large-scale stationary energy storage: Seawater batteries with high rate and reversible performance , 2019, Energy Storage Materials.

[41]  Wangwang Tang,et al.  Faradaic reactions in capacitive deionization (CDI) - problems and possibilities: A review. , 2018, Water research.