A Desalination BatteryMauro Pasta,Colin D.Wessells,Yi Cui,,and
Fabio La Mantia,*Analytische Chemie Zentrum fur Elektrochemie,
Ruhr-Universita t Bochum, Universita tsstrasse 150, D-44780 Bochum,
GermanyDepartment of Materials Science and Engineering, Stanford
University,Stanford,California 94305,United StatesStanford
Institute for Materials and Energy Sciences,SLAC National
Accelerator Laboratory,2575 Sand Hill Road,Menlo Park,California
94025,United States*S Supporting InformationABSTRACT: Water
desalination is an important approach toprovide fresh water around
the world, although its high energyconsumption, and thus high cost,
call for new, efficienttechnology. Here, we demonstrate the novel
concept of adesalinationbattery,
whichoperatesbyperformingcyclesinreverse onour previously
reportedmixing entropy
battery.Ratherthangeneratingelectricityfromsalinitydifferences,
asin mixing entropy batteries, desalination batteries use
anelectrical energy input toextract sodiumandchloride ionsfrom
seawater and to generate fresh water. The desalination battery is
comprised by a Na2xMn5O10 nanorod positive electrodeand Ag/AgCl
negative electrode. Here, we demonstrate an energy consumption of
0.29 Wh l1for the removal of 25% salt usingthis novel
desalinationbattery, whichis promisingwhencomparedtoreverseosmosis
(0.2Whl1), themost efficienttechnique presently available.KEYWORDS:
Seawater desalination,mixing entropy battery,reverse osmosis,ion
selectivityIncreasingamounts of freshwater will be
requiredinthefuture as a result of the increase in population and
enhancedliving standards, as well as the expansionof industrial
andagricultural activities.1,2At the current growth rate, humans
willconsume 90% of available fresh water by 2025,by which timethe
population living inwater-stressed areas is expected
toincreaseto3.9billion.3Seawater desalinationis becomingafeasible
source for fresh water, free fromlocal and globalvariations in
rainfall. For this reason, the use of seawaterdesalination has
steadily increased in recent years.Seawater desalinationprocesses
requireelectricor thermalenergytoseparatesalineseawater
intotwostreams, a freshwater stream containing a low concentration
of dissolved saltsand a concentrated brine stream. Avariety of
desalinationtechnologies have been developed over the
years.2,410Reverseosmosis requires a large electrical energy input,
which accountsfor44%of
itscost,1anditisbasedonselectivemembranes,which are prone to
fouling and require frequent replacement.11Recent research on
high-flux membranes based on carbonnanotubes12could potentially
reduce the energy
consumption,whilealternativeelectrical-baseddesalinationtechnologysuchas
ion concentration polarization in nanodevices13canpotentially avoid
the fouling.Thermal
energybasedmultistageflashdistillationrequiresenergy intensive
heating to temperatures above 90 C, accountsfor 50%of its
cost.1Multiple effect distillation is gainingpopularity due toits
higher efficiency andlower topbrinetemperatures (about 70 C) than
multistage flash technology.14Forward osmosis is a promising new
process that utilizes lowertemperatures (60 C) but still requires
the use ofmembranes.15,16Solvent extractionusingdirectional
solventslikedecanoicacidat mild temperatures(3050 C) has
beendemonstratedrecentlybyBajpayeeandco-workers.3Previouselectrochemical
approaches relying onthe electrical double-layer built at the
surface of highsurface area
carbonaceouselectrodesarecapacitivedeionization(CDI)17andthenewlydeveloped
capacitive double layer expansion (CDLE).18,19Despite these recent
advances, the 5080% target for reductionindesalinationcosts by
2020set by the National ResearchCouncil roadmap will not be
achieved by incrementalimprovements toexistingtechnologies,
andtherefore, anewapproach is needed.1Here we introduce a new
concept of a desalination batterywhich is based on a previously
described device known as
themixingentropybattery.20Thisdesalinationbatteryoperatesin a
similar way to the capacitive desalination techniques21butinstead
of storing charge in the electrical double layer (built
atthesurfaceof theelectrode)itisheldinthechemical bonds(bulk of the
electrode material). Battery electrodes offer higherspecific
capacity and lower self-discharge than capacitiveelectrodes.22In
this work, we reversed the previously proposed four stepcycle of
the mixing entropy battery, in a fashion similar to thefour
cyclesof theCDI andCDLE. ThisdesalinationbatteryReceived: November
4,2011Revised: December 27,2011Published: January
23,2012Letterpubs.acs.org/NanoLett 2012 American Chemical Society
839 dx.doi.org/10.1021/nl203889e | Nano Lett. 2012,12,
839843consists of a cationic sodium insertion electrode and a
chloride-capturing anionic electrode. A four-step
charge/dischargeprocess allows these electrodes to separate
seawater into freshwater andbrinestreams. Inthefirst step,
thefullychargedelectrodes, whichdonot containmobilesodiumor
chlorideions when charged, are immersed in seawater.
Aconstantcurrentisthenappliedinordertoremovetheionsfromthesolution
(Figure 1, Step 1). In the second step (Figure 1, Step2),
thefreshwater solutioninthecell isextractedandthenreplaced with
additional seawater. The electrodes are thenrechargedinthis
solution, releasing ions andcreating brine(Figure 1, Step 3). In
the final, fourth step (Figure 1, Step 4),the brine solution is
replaced with newseawater, and
thedesalinationbatteryisreadyforthenextcycle.
Freshwaterisproducedduringtheinitial dischargeof
theelectrodes(Steps12), while recharging the electrodes results in
the productionof a brine stream (Steps 34). Figure 1b schematically
shows atypical potential profile of a desalination battery as a
function ofchargestate. The circularintegralof thiscurve isequal to
thenet amount of electrical energy needed to drive the
desalinationof the seawater.23To demonstrate the validity of our
desalination batterydesign, electrochemical cell
employingthefollowingreactionwere constructed+ + + 5MnO 2Ag 2NaCl
Na Mn O 2AgCl2 2 5 10Anelectrodemadeof
Na2xMn5O10(NMO)nanorods20wasusedtocapture Na+ions, anda Ag
electrode was usedtocapture Clions (see Supporting Information for
detailedelectrode preparation). Among the few good water
compatibleNa+insertion materials now available, we selected
Na2Mn5O10Figure 1. (a) Schematic representation of the working
principle behind a complete cycle of the desalination battery,
showing how energy extractioncanbeaccomplished: step1,
desalination; step2, removal
ofthedesalinatedwaterandinletofsewwater;step3,
dischargeofNa+andClinseawater; step4, exchangetonewseawater.
(b)Typical formof acycleof batterycell
voltage(E)vscharge(q)inthedesalinationbattery,demonstrating the
energy consumed.Nano Letters Letterdx.doi.org/10.1021/nl203889e |
Nano Lett. 2012,12, 839843 840because of its higher specific charge
storage capacity (35 mAhg1), low cost, and benign environmental
impact.24,25Identifyinga suitableelectrode for chloridecapture is
moredifficult. Silver has been used because it forms AgCl,
bycapturing chloride ions, which is stable inpotential and
isinsoluble.The NMOhas been prepared by a polymer
synthesismethod,26with which nanorods with a mean diameter of 300nm
and length of about 2 m were obtained (Figure 2a-b). Thenanoscale
morphology of the NMO results in the exposure of ahigh surface area
to the solution, and therefore, fast exchange
ofionsbetweenthesolidandtheliquidphaseoccurs. Also, theshort
diffusionlengthwithinthe individual
NMOnanorodspermitsafasttransferofsodiumionsfromtheirsurfacesintotheir
bulk interiors. The NMO electrode was then prepared bydrop casting
a NMO-based ink on a carbon cloth currentcollector; these
electrodes showed typical electrochemicalbehavior when in contact
with sodiumcontaining electro-lytes.24,27A similar approach was
used for the Ag electrode, andin this case the ink contained silver
microparticles (0.51.0 mdiameter). Thechoiceof acarbonclothcurrent
collector isdictated by its corrosion resistance in highly saline
seawater. Inaddition, the superior adherence and soaking of the ink
into thecarbonfibersresultsinhighermassloading,
improvingdeviceperformance. The as-prepared Na2Mn5O10/AgCl cell
wassubjected to galvanostatic cycling in an aqueous
solutioncontaining 0.6 MNaCl in order to evaluate the
optimaloperational potential range (Figure 3a). Three reaction
plateausare observedat 0.3, 0.6, and1.0V, andeachone of
themcorresponds to the intercalation of Na+into a
crystallo-graphicallydistinct siteintheNMOstructure.
Thereactionplateauat 0.3Vis most desirable for use ina
desalinationbatterybecauseitishighlyreversiblewithlittleself-dischargeand
has a low enough potential to avoid oxygen gas evolution
inpH-neutral electrolytessuch as seawater.Electrochemical
impedancespectroscopy(EIS)wasusedtoidentify the limiting step in
the electrochemical reactionsoccurring in the cell.As shown in
Figure 3b,it is evident thatthe formation of AgCl on the surface of
the silver microparticlessubstantially increases the impedance of
the system. In contrast,the NMO electrode, which has a high surface
area, has a smallcharge transfer resistance, andis
diffusion-limited. It is notpossibletoaddress
throughthesemeasurements whether ornot the diffusion control is due
to the solution or to the solidstate.
Theresistanceofthesolutioninthedesalinationcell ismore than50%lower
thaninthe floodedcell due tothepositioning of the
electrodes.Desalination battery cycling was performed in a
custom-made plexiglass cell (see Supporting Information). The
cellpermits onlya two-electrodegeometry, withthreecompart-ments,
two for the two electrodes, and one for the electrolyte.The total
volume of the cell is around 300 L, and it exposes tothe solution 2
cm2of the electrodes. This cell geometry has theFigure2. SEMimages
of theas-preparedNa2Mn5O10showing(a)good uniformity of nanorod
morphology throughout the sample, and(b) nanorods with an average
size about 300 nm in width and 13 min length.Figure 3. (a)
Galvanostatic (1 mA) cycling of the Na2Mn5O10 (WE)Ag (CE) system
versus Ag/AgCl/KCl 3M. (b) Nyquist plot of the
EISspectrainthefrequencyrange100kHzto1Hzof: NMOworkingelectrode
(red curve), silver counter electrode before (blue curve) andafter
(green curve) chloride formation in a in seawater electrolyte witha
three electrode setup.Black curve is the spectra of the
desalinationcell.Nano Letters Letterdx.doi.org/10.1021/nl203889e |
Nano Lett. 2012,12, 839843 841advantage of a reducedohmic
dropandminimal processedvolume.The desalination cycle is started
with the electrode materialsin their charged state in seawater.
During the first step a 500Acm2current is applied, andions
areremovedfromthesolution. Through control of the total discharge,
the quantity ofions removedcan be controlled. The
desalinatedsolution wasthenremovedfromthecell
andreplacedwithnewseawater(Step 2).Then the desalinatedsolution was
analyzed by ICP-MS in order to evaluate the Coulombic efficiency of
thedesalinationprocess(Table1). Inthethirdstep, a+500Acm2current is
applied, charging the electrodes by releasing
theionsincorporatedinthefirststep. Theresultingconcentratedseawater
solution is then replaced with new seawater (Step
4),completingthecycle;thesystemisthenreadyforthefurthercycling.The
cycle for a 25%removal of chlorides is reportedinFigure4.
Thecircularintegral oftheEvsQcurverepresentstheenergyrequiredfor
thedesalinationprocess (removal of25% of salt) to take place, which
is on the order of 0.29 Wh l1.This valueis
verypromisingwhencomparedtothereverseosmosis under similar
conditions (0.2 Wh l1).13In Table 1, theresults of the ICP-MS
analysis of the seawater and
thedesalinatedseawaterarereportedforatheoretical removal of25 and
50% of chlorides, respectively. To address uncertainty
intheextractedvolumefromthedesalinationcell, sulfateionswere used
as a control in the experiment. Sulfate ions cannot beremoved by
using silver because Ag2SO4 is formed only at highvoltages (0.65
V/NHE) that are never achieved in thedesalination cell. All of the
other concentrations were obtainedbybringingtheconcentrationof
sulfateionsequal tothatinseawater. TheCoulombicefficiencies, C,
reportedinTable1are defined as = z Fn nQ( )C,ii I Fwhere ziis the
valence state of the ion, F is the Faradayconstant, nI and nF are
the initial and final number of moles inthe solution, and Qis the
total charge flown. Coulombicefficiencies, whichshould not be
confused withthe energyefficiency of the device, provide
information regarding theselectivity of the electrode material
toward the ions in solution.Infact, itisnotablethattheextractionof
cationsisnotNa+selectivebutalsoCa2+, Mg2+,
andK+areabletoinsertintheNMO structure. Comparison of the crystal
ionic radii of thesecations shows that Ca2+andNa+haveaverysimilar
radius(around115pm), Mg2+is smaller (around86), whileK+isclearly
bigger (ca. 150 pm). As consequence of this, it
isobserved(Table1)thatcalcium, magnesium,
andsodiumarealsoremovedfromseawater,
whilepotassiumisremovedtoalesser extent. The total Coulombic
efficiency of the desalinationcan be obtained from the value of
chlorides and is ca. 80%.
Theremainingcharge(about20%)islostduringthereductionofoxygen and
formation of OH.The desalination battery has simple construction,
uses readilyavailablematerials, has apromisingenergyefficiency,
operatesat roomtemperature with fewer corrosion problems
thanexisting desalination technology, and it could potentially be
Na+and Clselective, which would end the need for resalination.
Itsprimarylimitationof lowtotal ionextractionarisesfromthelow
specific charge capacity of the NMO sodium ion electrode(35 mAhg1vs
anaverage value of 160 mAhg1for Li-intercalating cathodes). This
lowcharge capacity limits thevolume of water that can be
desalinated within one cycle, andthereforetheoverall efficiencyof
desalination. However, thebattery research community has recently
shown increasinginterest
inaqueoussodiumionbatteriesforgridscalepowerstorage applications.
In the near future, higher capacity sodiumionelectrodes, as well as
improvedchloride electrodes
willmakethedesalinationbatteryafeasiblemethodforseawaterdesalination.
With regard to the chloride
intercalation/capturingelectrodematerial, silver shows several
advantages:stability of potential, corrosion resistance, and
bactericidalproperties. Nevertheless, the high price of silver, and
poorelectronicconductivityof AgCl,
whichistheprimarykineticlimitation of the desalination battery (see
SupportingInformation)will limit the utility of theAg/AgCl
electrodeinpractical devices. The workreportedhere demonstrates
theconcept of adesalinationbattery. Further developments willresult
in a versatile technology for the desalination of seawater,either
independently or through integration with otherdesalination
methods.ASSOCIATED CONTENT*S Supporting InformationAdditional
information, figures, and table. This material isavailable free of
charge via the Internet at http://pubs.acs.org.AUTHOR
INFORMATIONCorresponding Author*E-mail: [email protected]
1. ICP-OES/ICP-MS:Coulombic Efficiencies andSelectivity for Anions
and Cationsion Na+K+Mg2+Ca2+ClSO42sea water (mg/L) 11250 450 1400
450 18500 275025% removal(mg/L)9840 430 1130 280 14470
2750C,2547%
