GGA+Udescription of lithium intercalation into anataseTiO2

Abstract: We have used density-functional theory ͓generalized gradient approximation ͑GGA͔͒ to study lithium intercalation at low concentration into anatase TiO 2 . To describe the defect states produced by Li doping a Hubbard "+U" correction is applied to the Ti d states ͑GGA+ U͒. Uncorrected GGA calculations predict Li x TiO 2 to be metallic with the excess charge distributed over all Ti sites, whereas GGA+ U predicts a defect state 0.96 eV below the conduction band, in agreement with experimental photoelectron spectr… Show more

“…the viCGeletron ouple is seprted y severl lttie onstntsF he omprison yields stiliztion for hrges lolized on position Ti1 of 3 × 10 −2 eD while for hrges lolized on positions Ti2 nd Ti3 the stiliztion is 5 × 10 −2 eF his result is fully onsistent with wht reported y worgn etF lF25 D showing destiliztion of ∼ 5 × 10 −2 e when the viCGeletron ouple ws seprted y one or more lttie onstntsF uh smll vlues of intertion etween eletrons nd viC ions suggest tht the hrge loliztion energy is only mrginlly in)uened y the presene of nery vi ionD nd n e ompred to the loliztion of lone exess eletronD shown in pigure IF purther testing on viC ion nd eletron moilityD rried out vi the xif methodD on(rms tht the eletron hopping nd viC migrtion mehnisms re not in)uened y the reltive position of the two speies @pigure PAF he tivtion energy for viC migrtion etween othedrl vities in ulk ntse is HFTQ eD oth in sene nd presene of nery eletronD nd is in greement with other theoretil 25 nd experimentl 34 studiesF elso the mehnism of eletron hopping is not ltered y the presene of n djent interstitil viC ionD with n tivtion energy of HFPQ eD s for the migrtion of intrinsi ntse polrons 30 F huring oth viC nd eletron migrtionD the reltive position of the two speies ws onstntly monitoredD with no evidene of olletive migrtion of ions nd polronsD on(rming the smll intertion energy of the two speies in…”

“…Introduction hue to its verstility nd pplition in rnge of (elds @sensors 1,2 D tteries 3,4 D phototlE ysis 57 sensitized solr ells 8,9 A titnium dioxide is one of the most widely studied mterils oth from n experimentl nd theoretil point of view 1014 F iven if the rutile rystl phse is the most stle form of titnium dioxideD the ntse phse is often preferred due to its higher performne in iy 2 sed devies 1517 F sn dditionD some pplitions depend on of the presene of defets or impuritiesD either intrinsi or introdued vi dopingD to (nely tune the mteril properties 10,12 F es n exmpleD the presene of viC tions in the oxide struture uses positive shift of its vlene nd 18 D filitting eletron injetion from exited donors in sensitized solr ell devies 19 F smproved devie performne of solr ells with vi ontining eletrolytes my lso e relted to the role of vithium in the sensitizer surfeEtthment equiliriD nd on its intertion with injeted eletronsD 'eting the hrge trnsfer mehnisms ross the interfe nd in the sustrte 18 F vithium interlE tion in iy 2 is lso of tehnologil importne for energy storge in vi ion tteries 3,4 nd for oxygen nd humidity sensors 20 F e good understnding of the reltionship etween viC ionsD exess eletrons in the semionE dutor nd surfe dsortes is therefore neessry to design new omponents nd improve the existing devies performne in rnge of pplition (eldsF por thisD theoretil hp modelling is powerful tool to predit properties nd ehvior of oth moleulr nd solid stte systemsD with good lne etween omputtionl ost nd resulting preisionF he modelling of vi interlted iy 2 is however mde hllenging y the ft tht onventionl lol density pproximtion @vheA nd generl grdient pproximtion @qqeA sed funE tionls often fil in reproduing the eletrohemil properties of the semiondutorD suh s its nd gp or its eletron loliztion properties 21,22 F hi'erent pprohes to model suh systems were dopted in pst yersD rnging from moleulr mehnis lultions 23 to pure rrtreeEpok 24 nd hpC 25 F ell report preferentil viC segregtion in the (rst surfe lyers nd eletron loliztion in the viinity of the tionF roweverD onsistent R ssessment of the role of viC in oth ulk nd interfe systems is urrently missingD s well s ler distintion of the eletroni properties of surfeD susurfe nd ulk like deE fetsF his is minly due to the omputtionl ost nd omplexity of n urte eletroni struture modelD tht limits the dimension of the system under studyD onstrining it to high symmetry nd ion onentrtions 26 F emong the strtegies dopted to overome the shortE omings of qqe hpD hyrid funtionlsD in whih given mount of ext rrtreeEpok exhnge @7hfxA is introduedD re eoming inresingly populr 27,28 D even if results deE pend somewht on the hosen funtionl 29 F sn this workD hyrid hp investigtion of the lithium interlted ntse @IHIA sl is rried outD with speil fous on the viCGeletron intertion nd on the interfe propertiesF hetermining n ext vlue of 7hfx to dopt in the lultion on the sis of (ts to ulk properties is somewht ritrryD s it depends on whih ulk properties re onsidered for the (tF roweverD resonle rnge etween PS7 nd QS7 hfx hs previously een determined for polroni prope...…”

Excess Electrons and Interstitial Li Atoms in TiO₂ Anatase: Properties of the (101) Interface

“…the viCGeletron ouple is seprted y severl lttie onstntsF he omprison yields stiliztion for hrges lolized on position Ti1 of 3 × 10 −2 eD while for hrges lolized on positions Ti2 nd Ti3 the stiliztion is 5 × 10 −2 eF his result is fully onsistent with wht reported y worgn etF lF25 D showing destiliztion of ∼ 5 × 10 −2 e when the viCGeletron ouple ws seprted y one or more lttie onstntsF uh smll vlues of intertion etween eletrons nd viC ions suggest tht the hrge loliztion energy is only mrginlly in)uened y the presene of nery vi ionD nd n e ompred to the loliztion of lone exess eletronD shown in pigure IF purther testing on viC ion nd eletron moilityD rried out vi the xif methodD on(rms tht the eletron hopping nd viC migrtion mehnisms re not in)uened y the reltive position of the two speies @pigure PAF he tivtion energy for viC migrtion etween othedrl vities in ulk ntse is HFTQ eD oth in sene nd presene of nery eletronD nd is in greement with other theoretil 25 nd experimentl 34 studiesF elso the mehnism of eletron hopping is not ltered y the presene of n djent interstitil viC ionD with n tivtion energy of HFPQ eD s for the migrtion of intrinsi ntse polrons 30 F huring oth viC nd eletron migrtionD the reltive position of the two speies ws onstntly monitoredD with no evidene of olletive migrtion of ions nd polronsD on(rming the smll intertion energy of the two speies in…”

“…Introduction hue to its verstility nd pplition in rnge of (elds @sensors 1,2 D tteries 3,4 D phototlE ysis 57 sensitized solr ells 8,9 A titnium dioxide is one of the most widely studied mterils oth from n experimentl nd theoretil point of view 1014 F iven if the rutile rystl phse is the most stle form of titnium dioxideD the ntse phse is often preferred due to its higher performne in iy 2 sed devies 1517 F sn dditionD some pplitions depend on of the presene of defets or impuritiesD either intrinsi or introdued vi dopingD to (nely tune the mteril properties 10,12 F es n exmpleD the presene of viC tions in the oxide struture uses positive shift of its vlene nd 18 D filitting eletron injetion from exited donors in sensitized solr ell devies 19 F smproved devie performne of solr ells with vi ontining eletrolytes my lso e relted to the role of vithium in the sensitizer surfeEtthment equiliriD nd on its intertion with injeted eletronsD 'eting the hrge trnsfer mehnisms ross the interfe nd in the sustrte 18 F vithium interlE tion in iy 2 is lso of tehnologil importne for energy storge in vi ion tteries 3,4 nd for oxygen nd humidity sensors 20 F e good understnding of the reltionship etween viC ionsD exess eletrons in the semionE dutor nd surfe dsortes is therefore neessry to design new omponents nd improve the existing devies performne in rnge of pplition (eldsF por thisD theoretil hp modelling is powerful tool to predit properties nd ehvior of oth moleulr nd solid stte systemsD with good lne etween omputtionl ost nd resulting preisionF he modelling of vi interlted iy 2 is however mde hllenging y the ft tht onventionl lol density pproximtion @vheA nd generl grdient pproximtion @qqeA sed funE tionls often fil in reproduing the eletrohemil properties of the semiondutorD suh s its nd gp or its eletron loliztion properties 21,22 F hi'erent pprohes to model suh systems were dopted in pst yersD rnging from moleulr mehnis lultions 23 to pure rrtreeEpok 24 nd hpC 25 F ell report preferentil viC segregtion in the (rst surfe lyers nd eletron loliztion in the viinity of the tionF roweverD onsistent R ssessment of the role of viC in oth ulk nd interfe systems is urrently missingD s well s ler distintion of the eletroni properties of surfeD susurfe nd ulk like deE fetsF his is minly due to the omputtionl ost nd omplexity of n urte eletroni struture modelD tht limits the dimension of the system under studyD onstrining it to high symmetry nd ion onentrtions 26 F emong the strtegies dopted to overome the shortE omings of qqe hpD hyrid funtionlsD in whih given mount of ext rrtreeEpok exhnge @7hfxA is introduedD re eoming inresingly populr 27,28 D even if results deE pend somewht on the hosen funtionl 29 F sn this workD hyrid hp investigtion of the lithium interlted ntse @IHIA sl is rried outD with speil fous on the viCGeletron intertion nd on the interfe propertiesF hetermining n ext vlue of 7hfx to dopt in the lultion on the sis of (ts to ulk properties is somewht ritrryD s it depends on whih ulk properties re onsidered for the (tF roweverD resonle rnge etween PS7 nd QS7 hfx hs previously een determined for polroni prope...…”

Excess Electrons and Interstitial Li Atoms in TiO₂ Anatase: Properties of the (101) Interface

“…Our study used a localized basis set which was tuned to reproduce the cohesive energies of the components (i.e., of TiO 2 , Li, Na, and Mg) as described in Section 2.1.1. This resulted in good agreement with previous plane wave calculations of the Li-TiO 2 system [114,115]. It also resulted in the formation of gap states which were Ti d states, as expected, see Figure 9 (this is what is often referred to as the Ti 3+ , see below about charge and oxidation states).…”

“…It also resulted in the formation of gap states which were Ti d states, as expected, see Figure 9 (this is what is often referred to as the Ti 3+ , see below about charge and oxidation states). Previously it had been shown (in plane wave calculations) that either a hybrid functional or a Hubbard U correction was needed to reproduce such states, or else the electron donated by Li would occupy a state in the conduction band [114,115]. That we were able to obtain the correct electronic structure at the GGA level at the least shows that it can be done effectively; it also poses a question of whether the previously reported inability of the GGA approximation to model the gap states has to do not only with the limitation of the GGA approximation itself but also with the use of specific computational setups.…”

Insertion of Mono- vs. Bi- vs. Trivalent Atoms in Prospective Active Electrode Materials for Electrochemical Batteries: An ab Initio Perspective

“…Indeed, a scenario of mix-valence states can help in significantly improving the electronic conductivity of TiO 2 [41][42][43][44]. The simplest way to achieve this is through the synthesis of oxygen-deficient TiO 2 À δ , in which trivalent Ti is partially produced.…”

Ultrafast sodium storage in anatase TiO2 nanoparticles embedded on carbon nanotubes