A hybrid organic-inorganic perovskite with robust SHG switching

Mengjuan Yang，Hao Cheng，Yuqiu Xu，Mengzhen Li，Yong Ai

Ordered Matter Science Research Center，Nanchang University，Nanchang 330031，China

ABSTRACT Owing to the diversity of structure and potential applications in the field of electrics，sensors，and light-emitting diodes，lead halide perovskites have attracted great attention in recent years.Especially those lead halide perovskites with non-centrosymmetric crystal structures usually exhibit nonlinear optical(NLO)characteristics，which may endow them photoelectricity switching functionality.In this work，a lead-based hybrid organic-inorganic perovskite(HOIP)material，trimethyliodomethylammonium lead trichloride(TMIM·PbCl3)，is obtained on the basis of tetramethylammonium lead chloride through halogen substitution on the cation part.It shows dual-phase-transition behavior around 345 and 358 K，which is significantly improved.TMIM·PbCl3 crystallizes in the chiral space group， P212121，and shows a welldefined second harmonic generation(SHG)response，and good switching endurance，which makes it an excellent candidate for SHG switching material.This work highlights the importance of halogen substitution for crystal engineering and may pave way for the further exploration of the optoelectronic devices.

Keywords:Lead hybrid perovskite Second harmonic generation Single-crystal X-ray diffraction Nonlinear optical switching Halogen substitution

The perovskite with typical ABX3structures(A and B represent two different metal ions，and X represents an anion)，especially hybrid organic-inorganic perovskites(HOIPs)，have attracted widespread attention in the field of photoelectric devices due to their special optical and electric properties[1–6].Lead halide HOIPs(e.g.，MAPbI3)have been the most intensively investigated optoelectronic materials with their excellent advantages of tunable bandgap，facile synthesis method，and high absorption coeficient[7，8].However，the increasingly serious concerns of environment toxicity force researchers to explore the future environment friendly lead-free perovskites[9–11].Nevertheless，the lead halide HOIPs are sometimes the prior options for the research of switchable optoelectronic materials，sensors，solar cells，etc.because their properties can be tuned by external stimuli such as temperature，light，and electric[12–15].The HOIPs who crystallize in one of the 18 non-centrosymmetric point groups are second harmonic generation(SHG)active[16，17].For example，(DFCHA)2PbI4，and(4，4-DFHHA)2PbI4which crystallized in space groupCmc21andP21，respectively，exhibited strong SHG response[18，19].Materials for which the SHG signal could be switched between different states reversibly under external stimulation have been widely investigated for the application in the fields of photo-switching，electrooptical modulators[20–23].For instance，[NH3(CH2)5NH3]SbCl5and NH2-MIL-53(Al)have been reported with a well-defined SHG switching property[24，25].

Solid state materials with phase transition provide opportunities and possibilities to explore novel SHG switch materials based on structural phase transition with symmetry breaking[26，27].Reducing the symmetry of the crystals is an efficient way to obtain the non-centrosymmetric structures for crystal designing[28].The organic cationic part in the HOIP molecules is of great interest thanks to their particular nature that can be favorable to design the polar structure.Chemically modifying the organic moieties of the crystal could lead to the generation of the polarity.It was reported that，for many typical globular shape molecules like tetramethylammonium，quinine and DABCO(1，4-diazabicyclo[2，2，2]octane)，the halogen substitution could induce to crystalize in lower symmetry space group and enhance the phase transition point[29，30].By precise molecular modifications on such molecules，polar crystals and high phase transition temperature materials could be obtained.For example，polar crystals of(TMXM)FeBr3(X = F，Cl，Br，I)could be acquired through halogen substitution on the cation of the parent crystal(TM)FeBr3(TM，tetramethylammonium)[31].Again，halogen substitution leads to the non-centrosymmetric structures of(TMXM)MnX3(X = Cl，Br)[32]，and(TMCM)CdX3(X = Cl，Br)[33，34].In addition，halogen substitution can effectively increase the phase transition point.Such as(TMXM)2PtCl6(X = F，Cl，Br，I)[35].

Fig.1.(a)DSC curves acquired in a heating-cooling cycle of TMIM·PbCl3.(b)Temperature-dependence of the real part(ε′)of the dielectric constant of TMIM·PbCl3 at 1 MHz in heating-cooling run.(c)The dielectric constant(ε′)of TMIM·PbCl3 under different frequencies from 500 Hz to 1 MHz in heating run.(d)The switching cycles of the dielectric measurement for the TMIM·PbCl3.

Inspired by those works in designing polar crystal materials，we hereby report a lead-based 1D chain HOIP trimethyliodomethylammonium lead trichloride(TMIM·PbCl3).Thanks to the halogen-halogen interaction，TMIM·PbCl3crystalizes in a noncentrosymmetric space group，P212121，and has two solid-state phase transitions at 345 K(Tc1)and 358 K(Tc2)，respectively.Compared with the 225 K and 328 K of[(CH3)4N]4Pb3Cl10in Xue’s work[36]，the halogen substitution induces a significant increase in the phase transition temperature.TMIM·PbCl3shows a strong SHG response that is comparable to potassium dihydrogen phosphate(KDP)at room temperature.The SHG signal vanished immediately at temperature aboveTc2，which indicates a centrosymmetric feature of TMIM·PbCl3at its high-temperature phase.Moreover，TMIM·PbCl3shows good switching endurance，with switching contrast of ～2500，which makes it an excellent candidate for SHG switching material.This work will broaden the lead halide organic-inorganic hybrid SHG switches family.

The colorless neddle crystals of TMIM·PbCl3(Fig.S1 in Supporting information)were collected by evaporating the mixed clear solution of the trimethyliodomethylammonium chloride([TMIM]·Cl)and PbCl2.The phase transition behavior of TMIM·PbCl3was firstly studied by differential scanning calorimetry(DSC)with the PerkinElmer Diamond DSC instrument.As shown in Fig.1a，the endothermic peaks during the heating process and corresponding exothermic peaks in the cooling process suggest two reversible temperature-dependent thermal phase transitions.The transition temperatures are deduced as 345 K(Tc1)and 358 K(Tc2)from the heating peaks.For convenience，we name the phase below 345 K as low-temperature phase(LTP)，the phase above 358 K as hightemperature phase(HTP)，and the phase between the two as intermediate temperature phase(ITP).According to the formulaΔS=ΔH/T，the entropy changeΔSof the two endothermic peaks is calculated as 0.46 and 6.79 J mol-1K-1，respectively.The calculatedNvalues are 1.16(Tc1)and 2.24(Tc2)based on the Boltzmann equationΔS=Rln(N)，where R represents the gas constant andNstands for the possible orientations number.Such largeNvalues reveal that the compound has a reversible transition between ordered and disordered states[37].Structural changes are usually accompanied by a variation on calorific value during the heating/cooling progress.The endothermic and exothermic behaviors of phase transition materials endow them a wide range of applications in thermal storage devices[38，39].In order to explore the thermal stability of TMIM·PbCl3，we conducted a thermogravimetric(TGA)analysis[40，41].The weight percent versus temperature curve indicates that TMIM·PbCl3can bear the high temperature up to 520 K，which is 160 K higher thanTc2(Fig.S2 in Supporting information).The reversible thermal phase transition and thermal stability make it a potential heat storage material.

Fig.2.(a)Packing structures of TMIM·PbCl3 from b-axis in 293 K(LTP)and(b)348 K(ITP)，showing the similarities of the crystal structures and the differences of ordered states of the organic TMIM cations.The dashed lines stand for the Cl···I edge interactions.(c)Distorted PbCl6 octahedron with inhomogeneous Pb–Cl bond lengths in 293 K and(d)in 348 K.H atoms were omitted for clarity.

To further explore the phase transition，we used the Tong hui TH2828A instrument to measure the compound dielectricε(ε=ε’-i-ε’’).Fig.1b shows the temperature-dependent dielectric constant of the real part of the complex permittivity(ε′)at 1 MHz.There are two reversible dielectric anomalies，which matched well with the phase transition temperature in DSC.The step-shaped dielectric anomalies from ITP to HTP indicates the mutation of dielectric constant in a narrow temperature range.Fig.1c shows the variation dielectric constant under different frequencies from 500 Hz to 1 MHz in heating run.There are obvious dielectric anomalies at low frequencies aroundTc2，and as the frequency increases，the amplitude of the change gradually decreases，which means that the crystal is sensitive to external frequencies.Since the dielectric properties are related to temperature，the temperature can be used as a control variable to switch the TMIM·PbCl3between ITP and HTP.To check the dielectric switching endurance，we carried out the switching of the capacitor by controlling the temperature aroundTc2.Fig.1d shows the dielectric constant of TMIM·PbCl3at 1 MHz under the heating-cooling cycles.The higher dielectric constant region with a temperature above 358 K(HTP)was defined as ‘Switch ON’，and the area between 346 and 358 K(ITP)as ‘Switch OFF’.It shows excellent reversibility and endurance.The on/off conversion by receiving and decoding thermal enables its potential applications for sensor devices.In addition，no obvious dielectric decay was observed during the cycles.

High-quality single crystals were selected for the X-ray Diffraction(XRD)measurement.Rigaku Oxford Diffraction was used to collect variable temperature Single-crystal XRD data with MoKαradiation(λ= 0.71073 ?A)at 293 K(LTP)，348 K(ITP)，and 383 K(HTP).TMIM·PbCl3was refined as the non-centrosymmetric space groupP212121(No.19)at LTP.It has a typical ABX3perovskite structure.The asymmetric unit consists of one TMIM cation，six Cl-ligands and one Pb2+atom(Fig.S3 in Supporting information).The unit cell parameters area= 7.7839(6)?A，b= 9.2515(8)?A，c= 16.1914(14)?A，α=β=γ= 90°，andV= 1165.99(17)?A3(Table S1 in Supporting information).As shown in Fig.2a，the anionic part[PbCl3]-nhas a typical one-dimensional chain structure that grows along thea-axis.TMIM cations are in the ordered state at room temperature and occupy the cavities in between adjacent[PbCl3]-nchains with the face-sharing PbCl6octahedra structures.At 348 K，it still crystallizes in theP212121space group with cell parameters ofa= 7.7947(7)?A，b= 9.2974(11)?A，c= 16.1305(17)?A，andV= 1169.0(2)?A3，(Table S1).Although the unit cell parameters of TMIM·PbCl3in LTP and ITP are very similar，there are obvious changes in structure.The organic cations of the mesophase become disordered from LTP to ITP is shown in Fig.S4(Supporting information).From the point of view of crystal engineering，hydrogen bonding and halogen bonding is vital for crystal growth[33，42，43].According to the geometric model established by Desiraju，the halogen···halogen interaction X1= X2(X1/= X2)can be divided into two possible types based on the differentθ1andθ2values，whereθ1= C-Xheavy···Xlight，andθ2= C-Xlight···Xheavy.For the type I，θ1=θ2，while for the type II，θ1≈180° andθ2≈90°[44].TMIM·PbCl3should be treated as the type II withθ1andθ2values of 153.7°and 75°，respectively(Fig.S5 in Supporting information).The halogen···halogen interaction between the TMIM cations and the[PbCl3]-nchains form the C-I···Cl-Pb bond with a bond length of 3.303(7)?A at room temperature，as shown in Fig.S2.It was reported that the strength of halogen bonds as the halogen varied from F，Cl to Br[30，33].The I···Cl halogen bond in the crystal of TMIM·PbCl3is considerably strong for crystal packing.Such halogen bonds cause the inhomogeneous Pb-Cl bond lengths(Figs.2c and d，Table S2 in Supporting information)and the strong distortion in the octahedra of PbCl6.The octahedral distortion parameter(Δd)was described by the formula as following[45，46]:

Wherednrepresents the Pb-Cl bond length，anddrepresents the average Pb-Cl bond length，the calculatedΔdis 4.05 × 10-3，which is much greater than those reported lead halide perovskites，such as(C5H13N2)PbCl4·H2O(Δd= 2.031 × 10-3)[47]，(DMEN)PbBr4(Δd= 1.74 × 10-3)，(C6H13N3)PbBr4(Δd= 2.6 × 10-3)[48].Because of the ‘stretching’of the I···Cl halogen bond interaction，the[PbCl3]-nchains are no longer straightforward alonga-axis.Instead，as shown in Figs.2a and b，they show a zigzag conformation，which leads TMIM·PbCl3to crystallize in the chiral space group，P212121.This phenomenon is very different from the typical one-dimensional transition metal halogen chains formed perovskites，such as TMBM-MnBr3[32]，(3-pyrrolinium)-CdBr3[49]，R/S-CYHEAPbI3[50]and C4N2H14PbCl4[51].

We further measured the crystal structures of TMIM·PbCl3in the HTP，but it failed because of the weak diffraction.Fortunately，the unit cell parameters were obtained and the hexagonal or trigonal crystal system with cell parameters ofa= 9.3601(11)?A，b= 9.3601(11)?A，c= 7.8947(11)?A，α=β= 90°，γ= 120° were collected.In order to explore the structure at HTP，variable temperature powder X-ray diffraction(PXRD)was carried out by Rigaku D/MAX 2000 PC X-ray diffractometer.The simulated and the measured PXRD at room temperature matched well with each other，which supports the purity of the TMIM·PbCl3(Fig.S6 in Supporting information).The PXRD patterns of TMIM·PbCl3are quite similar in the LTP(i.e.，293 K，313 K，333 K)，which indicates that the same phase and no phase change occurs.When the temperature rises betweenTc1andTc2(i.e.，348 K，353 K)，the PXRD pattern changes significantly.As depicted in region B of Fig.3a，the intensity of the diffraction peak at 19.1° increases.In region D，the two diffraction peaks at 29.2° and 29.34° merge into a new peak at 29.18°.When the temperature goes to HTP(363 K，383 K)，the diffraction peak at 12.54° in area A and the diffraction peak at 22.9° in area C disappear.The absence of peaks under heating indicates that the crystal has undergone a phase transition from a low symmetry phase to a high symmetry phase.

Fig.3.(a)Variable-temperature PXRD pattern of TMIM·PbCl3 obtained in the temperature range 293–383K.(b)Switchable conversion of SHG signals between high-NLO and low-NLO states.(c)Oscilloscope traces of the SHG signals of TMIM·PbCl3 and KDP at room-temperature.(d)Completely reversible and recoverable switching of NLO effects.

As shown in Fig.3c，the SHG intensity of TMIM·PbCl3is comparable with that of the potassium dihydrogen phosphate(KDP)at room temperature.The strong nonlinear optical(NLO)characteristic of TMIM·PbCl3can be attributed to its chiral nature(P212121space group)，which is originated from I···Cl halogen···halogen interaction.According to the variable temperature-dependent SHG measurement in Fig.3b，the SHG signal starts to drop dramatically at 350 K until the background value at 355 K.The transition temperature(Tc2)deduced from SHG versus temperature curve matched well with that obtained from DSC and the dielectric measurements.The weakening of the signal from 350 K is due to the cations disorder in the crystal structure under heating.Above 355 K，the vanishing of the SHG signal reveals the centrosymmetric crystal feature of TMIM·PbCl3.

SHG switching property was then investigated.Fig.3d shows the SHG switching cycles of TMIM·PbCl3.For convenience，we label the high NLO state as ‘On’and the low NLO state as ‘Off’.The SHG switching maintains the excellent stability.It shows a strong endurance for the fact that it maintains its intensity without significant attenuation during the cycles.Besides，the SHG switcing contrast(the ratio of the on/off intensity)is as large as ～2500，which is higher than those known NLO materials(～150 for singlecomponent plastic crystal[27];～40 for organic NLO material[23];～38 for metal-organic framework[24])，indicating its good SHG switching performance.The bistable SHG feature of TMIM·PbCl3makes it an excellent candidate as SHG-switching lead-based perovskites material.

In summary，the ABX3type perovskite material TMIM·PbCl3undergoes two phase transitions around 345 and 358 K.The dual phase transition behavior was carefully investigated by DSC，temperature-dependent dielectric，single-crystal XRD，and variable temperature PXRD.The structural phase transitions are mainly due to the order to disorder change of organic cations under heating.Thanks to the halogen-halogen interaction of C-I···Cl-Pb between the organic cations and anionic[PbCl3]-nchains，TMIM·PbCl3crystallizes in the non-centrosymmetric space group，P212121at room temperature.TMIM·PbCl3shows a strong SHG signal and robust switching endurance.Therefore，the halogen substitution on globular shape molecules assists the exploration of the lead halide HOIPs type optoelectronic devices.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgments

This work was supported by the National Natural Science Foundation of China(No.21901099).

Supplementary materials

Supplementary material associated with this article can be found，in the online version，at doi:10.1016/j.cclet.2021.08.098.