Abstract
Converse flexoelectricity is a mechanical stress induced by an electric polarization gradient. It can appear in any material, irrespective of symmetry, whenever there is an inhomogeneous electric field distribution. This situation invariably happens in piezoresponse force microscopy (PFM), which is a technique whereby a voltage is delivered to the tip of an atomic force microscope in order to stimulate and probe piezoelectricity at the nanoscale. While PFM is the premier technique for studying ferroelectricity and piezoelectricity at the nanoscale, here we show, theoretically and experimentally, that large effective piezoelectric coefficients can be measured in nonpiezoelectric dielectrics due to converse flexoelectricity.
Introduction
Piezoresponse force microscopy (PFM) has become the goto technique for characterizing piezoelectricity at the nanoscale (particularly in ferroelectric thin films) and manipulating ferroelectric polarization^{1,2}. It is also often used as a tool to aid establishing whether or not materials are ferroelectric or piezoelectric; however, as has been pointed out^{3,4,5,6,7,8}, this latter use is delicate, because there are other physical phenomena that can yield a piezoelectriclike response in PFM without the material in question having to be piezoelectric.
PFM operates by delivering a voltage V to the surface of the material via an electrically conducting tip in an atomic force microscope (AFM). However, the application of the conductive tip directly on the sample leads to an effective piezoelectric coefficient that may not coincide with the intrinsic piezoelectric coefficient of the material. Even in the ideal case of a homogeneous and insulating piezoelectric, the electric field itself is not evenly distributed across the material, so the measured piezoelectric coefficient is an average of the fieldinduced deformation across the excited volume^{2}. In addition, electric fields and tipinduced strain gradients can cause changes in the local concentration of free ions in ionconducting solids, thereby expanding or contracting the local volume and thus giving a piezoelectriclike deformation caused by voltage. This effect is at the base of socalled electrochemical strain microscopy^{5,9,10}.
Another relevant electromechanical coupling mechanism in PFM is flexoelectricity^{11,12}. Direct flexoelectricity is a property allowed by symmetry in all materials, and it describes the appearance of polarization in response to a strain gradient. Converse and inverse flexoelectricity are the reverse phenomena of strain induced by polarization gradient^{13} and strain gradient induced by polarization^{14}. The inverse and converse flexoelectric effects have been experimentally demonstrated by, respectively, applying a voltage to a capacitor and measuring its bending^{14,15} and by applying a voltage across a truncated pyramid so as to generate an inhomogeneous electric field inside it, thus causing the sample to deform^{16,17,18,19,20}.
Converse flexoelectricity, like direct flexoelectricity, is allowed by symmetry in all materials—including nonpiezoelectric ones. Therefore, it should be a necessary ingredient of any PFM measurement because, when a voltage is applied to the tip, it generates an electric field that decays as we move away from its apex, resulting in an approximately radial electric field gradient. This electric field gradient must induce a converseflexoelectric strain. Dividing the converseflexoelectric strain by the voltage applied to the tip will yield a nonzero effective piezoelectric coefficient in any dielectric material. Here we demonstrate the existence of such converse flexoelectric effect in PFM, and show that it is quantitatively important, yielding significant piezoelectriclike response even if the material is ionically insulating and nonpiezoelectric.
Results
Selfconsistent simulation
Flexoelectricity is a twoway coupling between polarization and strain gradient and, conversely, between strain and polarization gradient. Both direct and converse flexoelectricity are characterized by the same fourth rank tensor, and are hence allowed in centrosymmetric materials^{12,21}. The converseflexoelectric stress is expressed mathematically as:
where σ is the mechanical stress, E is the electric field and μ is the fourthorder flexoelectric tensor. The excited volume below the PFM tip is subject to the converse flexoelectric effect due to the inhomogeneous nature of the electric field emanating from the tip (see Fig. 1). According to the Coulomb’s law, the electric field would decay as we move away from the tip, in a manner approximately equal to r^{−2} (this field profile is modified by the contrast between the susceptibility in the atmosphere and inside the sample, but the physical principle still stands). The gradient of this electric field must induce a strain via the converse flexoelectric effect, see Eq. (1).
The exact solution of the problem is complicated due to complex interactions between the tip, the surface and the electromechanical response of the sample. In addition, the shape and size of the contact area is itself a complex function of the amount of force with which the tip is pressing on the surface, the exact tip shape and the elastic properties of both the tip and the sample. Moreover, the applied tip pressure induces strain gradients in the contact region. These also induce polarization by direct flexoelectricity. This polarization selfconsistently modifies the electric field in the material by direct flexoelectricity and hence affect the nominal converse flexoelectric response.
In the absence of an analytical solution for this complex problem, we examine the role of converse flexoelectricity on the PFM response using a selfconsistent computational model^{22}, based on a linear continuum theory of piezoelectricity^{23}, augmented with flexoelectricity. In this model, direct and converse flexoelectricity are intimately intertwined manifestations of the same coupling. The total electromechanical energy \(({\cal H})\), resulting fourthorder continuum equations and a meshfree discretization method for solving numerically these equations are described in Supplementary Note 1.
In this work, the AFM tip is approximated as an ideal rigid sphere in contact with an ideal flat surface, see Fig. 2a. To model a frictionless contact, we follow the wellknown SignoriniHertzMoreau model^{24,25}, which allows us to either control the tip indentation and measure force, or control force and measure the displacement of the indenter (cf. Supplementary Note 2). We consider the strong indentation limit for the electrical boundary conditions on the contact area^{26}, which implies that the electroelastic response of the sample dominates over electrostatic tipsurface interactions. The strong indentation limit assumption is valid for an applied force of F > 100 nN, commonly used in PFM, for a typical tip radius of 50–100 nm^{26}. In this limit, the electrical boundary conditions are:
where a is the contact radius, ϕ is the electric potential, V is the tip voltage, and D_{z} is the vertical electric displacement. The bottom side of the model is connected to the ground, i.e., the electric potential is fixed to zero, see Fig. 2b, c. We assume the chargefree condition D_{n} = 0 for all other faces of the computational domain, where D_{n} is the normal electric displacement. Additional higherorder boundary conditions also arise from flexoelectricity^{22,27} (Supplementary Note 1).
An important feature of the response is the size effect, because flexoelectricity is caused by a gradient: the sharper the contact is, the stronger the gradient will be, and thus the larger the flexoelectricallyinduced deformation^{12}. Moreover, the contact area between tip and surface grows as a function of the amount of force with which the tip is pressed onto the surface. Accordingly, we can expect that, upon increasing loads, the contact area increases, and thus the AFM tipinduced electric field gradient in the sample decreases. Gradientinduced apparent piezoelectricity will, therefore, be inversely proportional to contact force. This feature emerges as a useful tool to differentiate the converse flexoelectric electromechanical response from the regular piezoelectric response or the electrochemical strain, for which no dependence on the contact area should be observed^{5,28}.
These qualitative predictions are quantitatively supported by numerical calculations. In Fig. 3, we show the simulation results for the effective piezoelectric coefficient as a function of contact radius and contact force, calculated for nonpiezoelectric SrTiO_{3}. The simulation protocol is as follows. We first progressively indent until reaching the desired force F at V = 0, and then the force is kept constant as the tip is electrically biased and the induced displacement under the tip Δu_{z} recorded. The effective piezoelectric coefficient is calculated as \(d_{33}^{{\mathrm{eff}}} = {\mathrm{\Delta }}u_z/V\), where Δu_{z} is the tip vertical displacement under the tip voltage V, obtained from the simulation results (material parameters and details are given in Supplementary Note 2 and Supplementary Table 1). These calculations are compared against the simulation results obtained for a piezoelectric material quartz, neglecting flexoelectricity and assuming an effective piezoelectric coefficient \(d_{33}^{{\mathrm{eff}}} = 2.5\,{\mathrm{pmV}}^{  1}\). As expected, the pure piezoelectric response shows no dependence on the applied force F. Therefore, one can use either force or contact area dependence as a means to qualitatively distinguish between flexoelectricity and piezoelectricity. This flexoelectric size effect will be important in comparison with the experimental results.
PFM experiment on nonpiezoelectric dielectrics
In order to validate our theoretical predictions, we have examined the piezoresponse of two different nonpiezoelectric dielectrics, SrTiO_{3} (STO) and TiO_{2}. The former is a cubic material with an effective flexoelectric coefficient of \(\mu _{13}^{{\mathrm{eff}}} = 2.5\,{\mathrm{nCm}}^{  1}\)^{29} while the latter has a rutile structure and an effective flexoelectric coefficient of \(\mu _{13}^{{\mathrm{eff}}} = 1.7\,{\mathrm{nCm}}^{  1}\)^{30}. The tips used were conductive diamondcoated Nanosensors CDT NCLR tips (k ≈ 72 Nm^{−1}, R_{tip} ≈ 100 nm). In order to ensure that the applied pressure did not change the shape of the tip (and thus the validity of the contact model), we recorded highresolution scanning electron microscopy images of the tips before and after the image. Using AFM, we also scanned the surface topography of the crystal before and after our piezoresponse characterization, to verify that there was no mechanical damage of the sample (Supplementary Note 5, Supplementary Figure 5). The effective piezoelectric coefficient \(d_{33}^{{\mathrm{eff}}}\) as a function of tip load is shown in Fig. 4a for the STO crystal, and compared with the result of the theoretical calculations. The agreement is remarkable, considering that the calculation is done without any fitting of parameters. The qualitative trend of the curve as a function of force is also an important evidence; if the piezoresponse of the STO sample were due to piezoelectricity^{31}, the piezoresponse should not depend on the indentation force (see Fig. 3). We note that Fig. 4b shows that the decrease in piezoresponse with increasing force is not due to a blunting of the tip, which remains spherical (with a relatively big radius due to its diamond coating) after the measurement. Meanwhile, the electromechanical response of TiO_{2} is reduced by a factor of 0.74, as compared to STO, a proportion in agreement with the reduction of the corresponding flexoelectric coefficients (Supplementary Note 6, Supplementary Figure 6).
We also show that this response is not associated with electrochemical strain because the signal is not hysterestic and the temperature dependence is the opposite (decreases with temperature) of what one should expect if the origin was ionic conductivity (Supplementary Note 3–4, Supplementary Figure 2–4). We also discard a major contribution of the direct flexoelectric effect. The tipinduced strain gradient makes the material locally polar and thus piezoelectric, but this contribution has been observed to be proportional to the applied force: the bigger the tip pressure, the bigger the flexoelectricallyinduced polarization^{32,33}. In contrast, the experimental results in Fig. 4a show that the converse flexoelectric contribution is inversely proportional to the applied force, indicating that the dominant effect is the converse rather than direct flexoelectricity. The prevalence of converse flexoelectricity at low contact forces is also relevant because most PFM experiments are done under modest indentation forces of the order of 100 nN, which is the regime where our calculations and measurements show the strongest flexoelectricallyinduced piezoelectricity.
Discussion
The theoretical calculations, done without fitting parameters, show that apparent piezoelectric coefficients as high as 15 pmV^{−1} can be measured in a cubic, nonpiezoelectric material such as SrTiO_{3}. To put this number into context, this effective piezoelectric coefficient is about 6 times bigger than that of quartz, and similar to the piezoelectric coefficient of ZnO^{34,35}. Highperformance perovskite ferroelectrics, of course, have considerably larger piezoelectric coefficients (1–2 orders of magnitude bigger), but their piezoelectric coefficients are smaller in thin film form—which is the type of sample typically probed by PFM. Perovskite ferroelectric thin films typically display piezoelectric coefficients of the order of tens, exceptionally low hundreds, of pmV^{−1}, and thus converse flexoelectricity can represent a significant fraction of their total electromechanical response. Here it is important to emphasize that flexoelectricity can and does coexist with true piezoelectricity in ferroelectrics. This coexistence can lead to qualitatively distinct behaviour. In particular, the amplitude of the piezoresponse, which is independent of polarity when intrinsic piezoelectricity is the dominant effect, can be polarity dependent when flexoelectricity and piezoelectricity compete^{36}.
The situation, of course, is more dramatic when the material that is being studied is not truly piezoelectric, in which case the entire electromechanical signal arises from other physical phenomena. We emphasize, however, that the flexoelectricallyinduced deformation is not an artefact: the effect is real, reproducible and inherent to any dielectric material. What is wrong is the interpretation of this voltageinduced deformation as piezoelectricity. The bottom line is that, since everything will look piezoelectric under a PFM, we cannot rely on this tool alone to determine whether a material is truly piezoelectric.
Methods
Selfconsistent continuum model of flexoelectricity
The selfconsistent electromechanical field equations of flexoelectricity are a coupled system of fourthorder partial differential equations (PDEs) which demands at least C^{1} continuous basis functions for a direct Galerkin method. To tackle the difficulty of solving these higherorder PDEs in a complex setup such as PFM, we resort to local maximumentropy (LME) meshfree approximants^{37}. The basis functions exhibit C^{1} smoothness, and therefore a straight Galerkin approach is possible. The potential of the resulting computational model to simulate challenging setups, such as pyramid compression for quantifying flexoelectricity^{20,22}, fracture of ferroelectrics to reveal the fundamental manifestation of flexoelectricity in fracture physics^{38}, and piezoelectric bimorphs^{39} unveiling complex interactions between piezo and flexoelectricity, has been demonstrated. The details of this model are presented in Supplementary Note 1. We extend this model to contact problems to simulate the PFM experiment by considering the contact energy and its discrete form (Supplementary Note 2, Supplementary Figure 1).
Experimental measurement of effective piezoelectric coefficient
The effective electromechanical response was measured using a MFP 3D Asylum Research AFM. A V_{ac} voltage was applied to the AFM tip at a frequency of 135 kHz and the obtained mechanical deformation h of the surface was measured by the AFM cantilever net deflection out of resonance conditions. The deflection signal of the cantilever was externally analyzed with a SR844 LockIn Amplifier to enhance the signal to noise ratio and the amplitude of the oscillation h (pm) was recorded. To obtain the effective piezoelectric coefficient, the V_{ac} voltage was applied following a triangular function with a V_{ac} amplitude of ±10 V and a period of 80 s. The \(d_{33}^{{\mathrm{eff}}}\) was then calculated as the slope of the linear fit between the amplitude of the mechanical oscillation of a tip (deflection) as analyzed by the external lockin amplifier and the excitation voltage, following the relationship \({\mathrm{\Delta }}h = V_{{\mathrm{ac}}}d_{33}^{{\mathrm{eff}}}\).
Code availability
The selfconsistent computational model is implemented using an inhouse C++ library. The library source code is available from the authors upon reasonable request.
Data availability
All data presented in this work are available from the authors upon reasonable request.
References
 1.
Gruverman, A. & Kalinin, S. V. Piezoresponse force microscopy and recent advances in nanoscale studies of ferroelectrics. J. Mater. Sci. 41, 107–116 (2006).
 2.
Bonnell, D. A., Kalinin, S. V., Kholkin, A. L. & Gruverman, A. Piezoresponse force microscopy: A window into electromechanical behavior at the nanoscale. Mrs. Bull. 34, 648–657 (2009).
 3.
Johann, F., Hoffmann, Á. & Soergel, E. Impact of electrostatic forces in contactmode scanning force microscopy. Phys. Rev. B 81, 094109 (2010).
 4.
Huey, B. D. et al. The importance of distributed loading and cantilever angle in piezoforce microscopy. J. Electroceram. 13, 287–291 (2004).
 5.
Morozovska, A. N., Eliseev, E. A., Balke, N. & Kalinin, S. V. Local probing of ionic diffusion by electrochemical strain microscopy: Spatial resolution and signal formation mechanisms. J. Appl. Phys. 108, 053712 (2010).
 6.
Seol, D., Kim, B. & Kim, Y. Nonpiezoelectric effects in piezoresponse force microscopy. Curr. Appl. Phys. 17, 661–674 (2017).
 7.
Balke, N. et al. Differentiating ferroelectric and nonferroelectric electromechanical effects with scanning probe microscopy. ACS Nano 9, 6484–6492 (2015).
 8.
Vasudevan, R. K., Balke, N., Maksymovych, P., Jesse, S. & Kalinin, S. V. Ferroelectric or nonferroelectric: Why so many materials exhibit “ferroelectricity” on the nanoscale. Appl. Phys. Rev. 4, 021302 (2017).
 9.
Balke, N. et al. Decoupling electrochemical reaction and diffusion processes in ionicallyconductive solids on the nanometer scale. ACS Nano 4, 7349–7357 (2010).
 10.
Jesse, S. et al. Electrochemical strain microscopy: Probing ionic and electrochemical phenomena in solids at the nanometer level. Mrs. Bull. 37, 651–658 (2012).
 11.
Nguyen, T. D., Mao, S., Yeh, Y.W., Purohit, P. K. & McAlpine, M. C. Nanoscale flexoelectricity. Adv. Mater. 25, 946–974 (2013).
 12.
Zubko, P., Catalan, G. & Tagantsev, A. K. Flexoelectric effect in solids. Annu. Rev. Mater. Res. 43, 387–421 (2013).
 13.
Yudin, P. V. & Tagantsev, A. K. Fundamentals of flexoelectricity in solids. Nanotech 24, 432001 (2013).
 14.
Bursian, E. V. & Zaikovskii, O. I. Changes in the curvature of a ferroelectric film due to polarization. Sov. Phys. Solid State 10, 1121–1124 (1968).
 15.
Bhaskar, U. K. et al. A flexoelectric microelectromechanical system on silicon. Nat. Nanotech. 11, 263–266 (2015).
 16.
Fu, J. Y., Zhu, W., Li, N. & Cross, L. E. Experimental studies of the converse flexoelectric effect induced by inhomogeneous electric field in a barium strontium titanate composition. J. Appl. Phys. 100, 024112 (2006).
 17.
Cross, L. E. Flexoelectric effects: Charge separation in insulating solids subjected to elastic strain gradients. J. Mater. Sci. 41, 53–63 (2006).
 18.
Zhu, W., Fu, J. Y., Li, N. & Cross, L. Piezoelectric composite based on the enhanced flexoelectric effects. Appl. Phys. Lett. 89, 192904 (2006).
 19.
Fu, J. Y., Zhu, W., Li, N., Smith, N. B. & Cross, L. E. Gradient scaling phenomenon in microsize flexoelectric piezoelectric composites. Appl. Phys. Lett. 91, 182910 (2007).
 20.
Abdollahi, A., Millán, D., Peco, C., Arroyo, M. & Arias, I. Revisiting pyramid compression to quantify flexoelectricity: A threedimensional simulation study. Phys. Rev. B 91, 104103 (2015).
 21.
Shu, L., Wei, X., Pang, T., Yao, X. & Wang, C. Symmetry of flexoelectric coefficients in crystalline medium. J. Appl. Phys. 110, 104106 (2011).
 22.
Abdollahi, A., Peco, C., Millán, D., Arroyo, M. & Arias, I. Computational evaluation of the flexoelectric effect in dielectric solids. J. Appl. Phys. 116, 093502 (2014).
 23.
Abdollahi, A. & Arias, I. Phasefield modeling of crack propagation in piezoelectric and ferroelectric materials with different electromechanical crack conditions. J. Mech. Phys. Solids 60, 2100 (2012).
 24.
Wriggers, P. Computational contact mechanics (Springer Berlin Heidelberg, 2006).
 25.
Yastrebov, V. A. and Breitkopf, P. Numerical Methods in Contact Mechanics (John Wiley and Sons, 2013).
 26.
Kalinin, S. V., Karapetian, E. & Kachanov, M. Nanoelectromechanics of piezoresponse force microscopy. Phys. Rev. B 70, 184101 (2004).
 27.
Codony, D., Marco, O., FernándezMéndez, S., and Arias, I. An Immersed Boundary Hierarchical Bspline method for flexoelectricity. Preprint at http://arxiv.org/abs/1902.02567 (2019).
 28.
Morozovska, A. N., Eliseev, E. A., Svechnikov, G. S. & Kalinin, S. V. Nanoscale electromechanics of paraelectric materials with mobile charges: Size effects and nonlinearity of electromechanical response of srtio_{3} films. Phys. Rev. B 84, 045402 (2011).
 29.
Zubko, P., Catalan, G., Buckley, A., Welche, P. R. L. & Scott, J. F. Straingradientinduced polarization in SrTiO_{3} single crystals. Phys. Rev. Lett. 99, 167601 (2007).
 30.
Narvaez, J., VasquezSancho, F. & Catalan, G. Enhanced flexoelectriclike response in oxide semiconductors. Nature 538, 219–221 (2016).
 31.
Biancoli, A., Fancher, C. M., Jones, J. L. & Damjanovic, D. Breaking of macroscopic centric symmetry in paraelectric phases of ferroelectric materials and implications for flexoelectricity. Nat. Mater. 14, 224–229 (2015).
 32.
Lu, H. et al. Mechanical writing of ferroelectric polarization. Science 335, 59–61 (2012).
 33.
Ocčenásšek, J. et al. Nanomechanics of flexoelectric switching. Phys. Rev. B 92, 035417 (2015).
 34.
Hutson, A. R. Piezoelectricity and conductivity in zno and cds. Phys. Rev. Lett. 4, 505–507 (1960).
 35.
Crisler, D. F., Cupal, J. J. & Moore, A. R. Dielectric, piezoelectric, and electromechanical coupling constants of zinc oxide crystals. Proc. IEEE 56, 225–226 (1968).
 36.
CorderoEdwards, K., Domingo, N., Abdollahi, A., Sort, J. & Catalan, G. Ferroelectrics as smart mechanical materials. Adv. Mater. 29, 1702210 (2017).
 37.
Arroyo, M. & Ortiz, M. Local maximumentropy approximation schemes: a seamless bridge between finite elements and meshfree methods. Int. J. Numer. Meth. Eng. 65, 2167–2202 (2006).
 38.
Abdollahi, A. et al. Fracture toughening and toughness asymmetry induced by flexoelectricity. Phys. Rev. B 92, 094101 (2015).
 39.
Abdollahi, A. & Arias, A. Constructive and destructive interplay between piezoelectricity and flexoelectricity in flexural sensors and actuators. J. Appl. Mech. 82, 121003 (2015).
Acknowledgements
G.C. and N.D. acknowledge financial support from ERC Starting grant 308023, from Plan Nacional project MINECO Grant MAT201677100C21P and FIS201573932JIN and support of Generalitat de Catalunya (Grant No. 2017SGR579). ICN2 acknowledges support from the Severo Ochoa Program (MINECO, Grant SEV20170706) and the CERCA Programme / Generalitat de Catalunya. I.A. acknowledges the support of the Generalitat de Catalunya through the prize “ICREA Academia” for excellence in research and of the European Research Council (StG679451). I.A. and A.A. also acknowledge the support of Generalitat de Catalunya (Grant No. 2017SGR1278).
Author information
Affiliations
Contributions
A.A. and N.D. contributed equally to this work. G.C. and N.D. performed and analysed the experiments. I.A. and A.A. developed the axisymmetric contact model and performed the simulations. G.C. wrote the paper with the help of all the other authors. All authors discussed the results, commented on the manuscript and gave their approval to the final version of the manuscript.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Journal peer review information: Nature Communications thanks John Gregg and the other anonymous reviewers for their contribution to the peer review of this work. Peer reviewer reports are available.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Abdollahi, A., Domingo, N., Arias, I. et al. Converse flexoelectricity yields large piezoresponse force microscopy signals in nonpiezoelectric materials. Nat Commun 10, 1266 (2019). https://doi.org/10.1038/s4146701909266y
Received:
Accepted:
Published:
Further reading

ThicknessDependent Piezoelectric Property from QuasiTwoDimensional Zinc Oxide Nanosheets with Unit Cell Resolution
Research (2021)

Strategies to instigate superior electromechanical response in dielectric materials via converse flexoelectricity
Extreme Mechanics Letters (2021)

Correlating Crystallographic Orientation and Ferroic Properties of Twin Domains in Metal Halide Perovskites
ACS Nano (2021)

Inplane polarization contribution to the vertical piezoresponse force microscopy signal mediated by the cantilever “buckling”
Applied Surface Science (2021)

Inverse Flexoelectret Effect: Bending Dielectrics by a Uniform Electric Field
Physical Review Applied (2021)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.