Abstract
Crystal symmetry governs the nature of electronic Bloch states. For example, in the presence of time-reversal symmetry, the orbital magnetic moment and Berry curvature of the Bloch states must vanish unless inversion symmetry is broken1. In certain two-dimensional electron systems such as bilayer graphene, the intrinsic inversion symmetry can be broken simply by applying a perpendicular electric field2,3. In principle, this offers the possibility of switching on/off and continuously tuning the magnetic moment and Berry curvature near the Dirac valleys by reversible electrical control4,5. Here we investigate this possibility using polarization-resolved photoluminescence of bilayer MoS2, which has the same symmetry as bilayer graphene but has a bandgap in the visible spectrum6,7 allowing direct optical probing5,8,9,10,11,12. We find that in bilayer MoS2 the circularly polarized photoluminescence can be continuously tuned from −15% to 15% as a function of gate voltage, whereas in structurally non-centrosymmetric monolayer MoS2 the photoluminescence polarization is gate independent. The observations are well explained as resulting from the continuous variation of orbital magnetic moments between positive and negative values through symmetry control.
Similar content being viewed by others
Main
The Dirac-valley degree of freedom has recently been considered for new modes of electronic and photonic device operation4,5,9,10,11,12,13,14,15,16,17 following the arrival of atomically thin two-dimensional (2D) electronic systems6,7,18,19 (Fig. 1a). In this context, phenomena such as valley polarization and anomalous valley- and spin-Hall effects have been discussed for the +K and −K Dirac valleys at opposite corners of the Brillouin zone in hexagonal systems9,10,11,12,15. The realization of these effects hinges on achieving control of valley contrast, that is, of properties that differ between the two valleys, in particular the magnetic moment (m) and Berry curvature (). Time-reversal symmetry dictates that each pseudovector, m as well as , has the same magnitude but opposite sign in the two valleys, whereas inversion symmetry requires them to have the same sign. Therefore, a necessary condition for valley-contrasting m and is inversion symmetry breaking4.
Monolayer MoS2 lacks structural inversion symmetry (Fig. 1a), and thus m and are non-zero, having equal magnitude but opposite signs in the two ±K valleys owing to time-reversal symmetry. One direct consequence of non-zero m is valley-contrasting optical dichroism5,8,9, whereby charge carriers in the two valleys can be selectively excited by circularly polarized optical fields9,10,11. This effect permits optical generation of valley polarization, as recently demonstrated using polarized photoluminescence measurements. However, continuous and reversible control of these valley-contrasting properties requires a system where the inversion symmetry can be controlled at will, which has not been achieved previously.
Unlike monolayer MoS2 with its structural inversion asymmetry9,20,21, pristine bilayer MoS2 is inversion symmetric (Fig. 1b)9,11,12. Thus, m and the consequent valley-contrasting dichroism vanish. However, inversion symmetry can be broken by applying an electric field perpendicular to the bilayer, which leads to a potential difference between the two layers (Fig. 1b, row 3). In bilayer graphene this perpendicular electric field produces a small bandgap2,3. In bilayer MoS2, which already has a bandgap in the visible6,7,19, the effect on the energy spectrum is negligible. This allows us to focus on the effect of the electric field on the orbital magnetic moments, which affect optical selection rules near the ±K valleys9 (Fig. 1c).
In our experiments, atomically thin MoS2 samples are mechanically exfoliated from bulk MoS2 crystals onto SiO2 (285 nm thick) on heavily doped silicon18. Figure 1d is an optical micrograph of a representative sample. The number of layers is identified by atomic force microscopy, as illustrated in Fig. 1e,f, where the profile along the white dashed line clearly shows monolayer steps with a thickness7,17 of about 7 Å. We then fabricate field-effect transistors (FETs) in which the back-gate voltage V g controls the perpendicular electric field (Fig. 1g; refs 17, 22, 23, 24 and Methods).
To perform polarization-resolved microphotoluminescence (see Methods for details), the excitation laser is incident normally on the sample, held at a temperature of 30 K, with a spot size of ∼2 μm. The laser intensity is 150 W cm−2 and the wavelength is 632 nm unless otherwise noted. After interband excitation, for example by σ+ light, the right- and left-hand-polarized photoluminescence signals, P(σ+) and P(σ−), are selectively detected. The degree of circular polarization is defined as η = (P(σ+)−P(σ−))/(P(σ+)+P(σ−)). Note that all of the photoluminescence spectra presented here show a sharp drop below 645 nm due to the spectral cutoff of the laser notch filter.
Figure 2a,b shows the polarization-resolved photoluminescence spectra for bilayer MoS2 on excitation by σ+ and σ−polarized light, respectively, at V g = 0 for bilayer device B1. There are two spectral features. The broad peak centred on 860 nm shows no circular polarization, as expected for phonon-assisted indirect interband transitions. This peak is not the focus of the paper but it provides a convenient non-polarized reference signal. In contrast, the photoluminescence at 650 nm, which is from direct transitions in the ±K valleys does show circular polarization. For σ+ excitation P(σ+) is larger than P(σ−) (Fig. 2a), and vice versa (Fig. 2b). The corrected polarization η is plotted against wavelength in Fig. 2c (see Methods). The increase in the magnitude of η towards shorter wavelength is characteristic of hot luminescence. The non-zero photoluminescence polarization at V g = 0 implies the existence of broken inversion symmetry in the as-prepared bilayer, consistent with a recent report11. All of our bilayer devices showed η ranging from ∼ 10 to ∼ 30% at V g = 0 (Supplementary Information), with no clear dependence on laser intensity.
Figure 2d is a 2D intensity plot of P(σ+) on σ+ excitation for bilayer device B2. The light emission is slightly blueshifted and its intensity decreases as V g decreases from positive to negative (Supplementary Information). The sharp vertical lines superimposed on the photoluminescence are Raman scattering peaks25,26,27. Interestingly, η changes markedly as a function of V g. Figure 2e is a colour map of η as a function of both wavelength and V g. The data clearly show that η depends strongly on V g and approaches zero around −60 V. This observation implies that the sample is initially electron doped17 (Supplementary Information).
The value of η at 648 nm (indicated by the dashed lines in Fig. 2e) is plotted against V g in Fig. 2f for σ+ (red) and σ− (blue) polarized light excitation. Together they form a striking X-shaped pattern. The photoluminescence polarization completely disappears at the centre of the X at V c = −60 V, and becomes finite on either increasing or decreasing V g from there. Furthermore, the dependence of η on V g is nonlinear: for |V g−V c|≳30 V it seems to approach saturation.
In sharp contrast, the spectra of monolayer MoS2 devices (five were measured) exhibit no appreciable V g dependence of η. Figure 3a illustrates photoluminescence spectra from monolayer device S1 under σ+ excitation at V g = 0. The broad peak centred at 705 nm is probably from impurities. It does not show appreciable polarization and its intensity strongly depends on V g (see Supplementary Information). In contrast, the narrower peak at 650 nm from transitions in the ±K valleys is strongly polarized10,11,12. The polarization η reaches as much as 0.8 in some devices. Figure 3b shows a map of photoluminescence intensity versus V g and wavelength for device S2. Again, the sharp vertical lines are Raman peaks that are superimposed on the photoluminescence of interest. The overall photoluminescence intensity has an appreciable dependence on V g, but now η remains constant as V g varies from −50 to 50 V, as can be seen in the map of η versus V g and wavelength in Fig. 3c. Figure 3d shows η versus V gat a wavelength of 648 nm for σ+ (red) and σ− (blue) excitation, illustrating the markedly different behaviour from the bilayer case (Fig. 2f).
We now turn to the interpretation of these results. In the following discussion, all circular dichroism should be taken to be valley contrasting. Generally speaking, circularly polarized band-edge photoluminescence originates from optical selection rules, and the degree of photoluminescence polarization is determined by both the degree of circular dichroism and the depolarization mechanisms. Circular dichroism is related to the orbital magnetic moment as discussed in refs 5, 8. In a hexagonal 2D crystal, for direct optical transitions at the ±K valleys between a pair of bands labelled n and s, the k-resolved absorption circular dichroism is given by χ(k) = (|P+ns(k)|2−|P−ns(k)|2)/(|P+ns(k)|2+|P−ns(k)|2), where P±ns(k) = 〈us(k)|Px±i Py)|un(k)〉 is the interband matrix element of the momentum operator and |us(k)〉 and |un(k)〉 are the Bloch functions. The orbital magnetic moment is given by5 , where μB is the Bohr magneton, me is free-electron mass, ɛn(k) is the dispersion of the nth band, and is perpendicular to the sheet. It can be seen from the relationship between these expressions that χ is finite when m is finite.
It has been established that the polarized photoluminescence in monolayer MoS2 originates from valley-contrasting circular dichroism9,10,11. Owing to absorption circular dichroism over a large range of k in each Dirac valley, circularly polarized light excites electrons preferentially in one valley producing valley polarization at the excitation energy. Because we detect photoluminescence from electrons that have relaxed to the band edge, the observed degree of photoluminescence polarization is determined by the absorption circular dichroism χ at the excitation energy and the valley depolarization rate (due to inter-valley scattering) during the hot-carrier relaxation. The large η observed here and in ref. 11 therefore implies not only large χ in a large neighbourhood around the K points, but also that the valley relaxation time is longer than the electron–hole recombination time. The lack of dependence of η on V g that we report here (Fig. 3d) demonstrates that the inter-valley scattering time remains long as the perpendicular electric field is changed. It also implies that both circular dichroism and m are little affected by the electric field, consistent with the fact that in monolayer MoS2 it is governed by the inherent structural inversion asymmetry.
The new X-shaped pattern of η versus V g we observe in the bilayer case (Fig. 2f) can be explained well by the relation between inversion symmetry and orbital magnetic moment. When inversion symmetry is present in the bilayer at V g = V c, m and the associated valley-contrasting optical dichroism disappear. For all other values of V g, inversion symmetry is broken and consequently non-zero m and valley circular dichroism appear near the band edge, which leads to finite photoluminescence polarization. Thus, the observation of finite ηsignifies electric-field-induced χ and m with long valley relaxation time. The bilayer configurations at the two gate voltages V g = V c±ΔV should be equivalent by spatial inversion, under which the +K and −K valley indexes are switched but the resulting photoluminescence polarization is unchanged. This is consistent with the pattern observed: η is always positive (negative) for σ+ (σ−) excitation and is symmetric with respect to V c, as evident in Fig. 2f. Our results therefore demonstrate that inversion symmetry breaking by a perpendicular electric field can be used not only to modify the dispersion of the electron states, as has been shown in bilayer graphene, but also to control the orbital magnetic moments of Bloch states (see Supplementary Information for explicit relations between m and and the gate electric field derived in the k · p approximation).
Although such an X-shaped pattern of η as a function of electric field has not been seen before, electric-field-dependent photoluminescence polarization is not unusual and has also been observed for example in GaAs quantum wells, where the polarization is related to spin and the electric field affects the spin depolarization rate28. In our case, the observation of η = 0 at V g = V c implies that spin relaxation is fast at the symmetry point, because the electrons remember none of the angular momentum of the absorbed light at that point. To explain the X-shaped pattern in terms of spin polarization one would have to assume that the spin relaxation rate decreases strongly with applied field away from the symmetry point. However, the spin relaxation rate is expected to be the smallest at the inversion symmetry point, for example a perpendicular electric field introduces Rashba spin–orbit coupling which normally increases the spin relaxation rate29. Furthermore, in the monolayer we observe a constant large photoluminescence polarization as a function of V g, incompatible with a changing spin relaxation rate. Our observations are perfectly explained by slow inter-valley scattering leading to valley polarization at the band edge combined with fast spin relaxation and negligible spin polarization. Tuning of the relaxation rates is unlikely to be the cause of the observation.
As discussed above, χ sets an upper bound on η. Therefore, we have performed ab initio density functional theory (DFT) calculations of both χ and m as a function of electric field in bilayer MoS2. Figure 4a shows the calculated χ when the excitation energy is ∼ 50 meV above the DFT bandgap, roughly the energy difference between the incident photons and the photoluminescence peak position. The calculation reproduces the X-shaped pattern and qualitatively agrees with the experimental observation. Figure 4b,c shows the calculated orbital magnetic moment at ±K valleys near the top valence band at various electric fields. We note that finite orbital magnetic moment also implies finite Berry curvature4,5,9,10, which also depends on the inter-band matrix element of the momentum operator and has a similar expression: . Hence, the valley-contrasting magnetoelectric effect represents possible electrical control of the Berry curvature, suggesting the possibility of manipulating topological quantum phenomena in atomically thin 2D materials.
Methods
Device fabrication.
Devices were fabricated using standard electron beam lithography techniques, using an FEI Sirion scanning electron microscope with a Nabity nanometre pattern generation system. An electron beam evaporator was then used to deposit 5 nm/50 nm of Ti/Au followed by a standard hot-acetone lift-off process.
Polarization-resolved photoluminescence.
The polarization-resolved photoluminescence set-up is equipped with a high-power microscope (Olympus), a low-temperature microphotoluminescence cryostat (Janis) and a spectrometer with a CCD (charge-coupled device) detector. Figure 1g shows the measurement scheme. A linearly polarized laser beam, either horizontal or vertical, is reflected by a dichroic beam splitter and then passed through a quarter-wave plate. The circularly polarized light, either σ+ or σ−, is focused by a ×40 objective lens onto the sample located in the cryostat. The photoluminescence signal is collected by the same lens and goes through the same quarter-wave plate. The σ+ (σ−) polarized photoluminescence is consequently converted to vertical (horizontal) linear polarization. The linearly polarized photoluminescence transmits through the dichroic beam splitter and is selectively detected with a linear polarizer. The measured photoluminescence polarization is corrected to compensate for the depolarization effects caused by the system, which mainly originate from the optics involved in the incident path and are determined by characterizing the beam polarization at the sample position. We also applied linearly polarized light to excite the device and confirmed that the resulting degree of polarization is zero.
References
Xiao, D., Chang, M-C. & Niu, Q. Berry phase effects on electronic properties. Rev. Mod. Phys. 82, 1959–2007 (2010).
Mak, K. F., Lui, C. H., Shan, J. & Heinz, T. F. Observation of an electric-field-induced band gap in bilayer graphene by infrared spectroscopy. Phys. Rev. Lett. 102, 256405 (2009).
Zhang, Y. et al. Direct observation of a widely tunable bandgap in bilayer graphene. Nature 459, 820–823 (2009).
Xiao, D., Yao, W. & Niu, Q. Valley-contrasting physics in graphene: Magnetic moment and topological transport. Phys. Rev. Lett. 99, 236809 (2007).
Yao, W., Xiao, D. & Niu, Q. Valley-dependent optoelectronics from inversion symmetry breaking. Phys. Rev. B 77, 235406 (2008).
Mak, K. F., Lee, C., Hone, J., Shan, J. & Heinz, T. F. Atomically thin MoS2: A new direct-gap semiconductor. Phys. Rev. Lett. 105, 136805 (2010).
Splendiani, A. et al. Emerging photoluminescence in monolayer MoS2 . Nano Lett. 10, 1271–1275 (2010).
Souza, I. & Vanderbilt, D. Dichroic f-sum rule and the orbital magnetization of crystals. Phys. Rev. B 77, 054438 (2008).
Xiao, D., Liu, G-B., Feng, W., Xu, X. & Yao, W. Coupled spin and valley physics in monolayers of MoS2 and other group-VI dichalcogenides. Phys. Rev. Lett. 108, 196802 (2012).
Zeng, H., Dai, J., Yao, W., Xiao, D. & Xiaodong, C. Valley polarization in MoS2 monolayers by optical pumping. Nature Nanotech. 7, 490–493 (2012).
Mak, K. F., He, K., Shan, J. & Heinz, T. F. Control of valley polarization in monolayer MoS2 by optical helicity. Nature Nanotech. 7, 494–498 (2012).
Cao, T., Feng, J., Shi, J., Niu, Q. & Wang, E. Valley-selective circular dichroism of monolayer molybdenum disulphide. Nature Commun. 3, 887 (2012).
Akhmerov, A. R. & Beenakker, C. W. J. Detection of valley polarization in graphene by a superconducting contact. Phys. Rev. Lett. 98, 157003 (2007).
Rycerz, A., Tworzydlo, J. & Beenakker, C. W. J. Valley filter and valley valve in graphene. Nature Phys. 3, 172–175 (2007).
Zhu, Z-G. & Berakdar, J. Berry-curvature-mediated valley-Hall and charge-Hall effects in graphene via strain engineering. Phys. Rev. B 84, 195460 (2011).
Korn, T., Heydrich, S., Hirmer, M., Schmutzler, J. & Schuller, C. Low-temperature photocarrier dynamics in monolayer MoS2 . Appl. Phys. Lett. 99, 102109 (2011).
Radisavljevic, B., Radenovic, A., Brivio, J., Giacometti, V. & Kis, A. Single-layer MoS2 transistors. Nature Nanotech. 6, 147–150 (2011).
Novoselov, K. S. et al. Two-dimensional atomic crystals. Proc. Natl Acad. Sci. USA 102, 10451–10453 (2005).
Eda, G. et al. Photoluminescence from chemically exfoliated MoS2 . Nano Lett. 11, 5111–5116 (2011).
Cheiwchanchamnangij, T. & Lambrecht, W. R. L. Quasiparticle band structure calculation of monolayer, bilayer, and bulk MoS2 . Phys. Rev. B 85, 205302 (2012).
Zhu, Z. Y., Cheng, Y. C. & Schwingenschlögl, U. Giant spin-orbit-induced spin splitting in two-dimensional transition-metal dichalcogenide semiconductors. Phys. Rev. B 84, 153402 (2011).
Yoon, Y., Ganapathi, K. & Salahuddin, S. How good can monolayer MoS2 transistors be? Nano Lett. 11, 3768–3773 (2011).
Popov, I., Seifert, G. & Tománek, D. Designing electrical contacts to MoS2 monolayers: A computational study. Phys. Rev. Lett. 108, 156802 (2012).
Radisavljevic, B., Whitwick, M. B. & Kis, A. Integrated circuits and logic operations based on single-layer MoS2 . ACS Nano 5, 9934–9938 (2011).
Lee, C. et al. Anomalous lattice vibrations of single- and few-layer MoS2 . ACS Nano 4, 2695–2700 (2010).
Jiménez Sandoval, S., Yang, D., Frindt, R. F. & Irwin, J. C. Raman study and lattice dynamics of single molecular layers of MoS2 . Phys. Rev. B 44, 3955 (1991).
Chakraborty, B. et al. Symmetry-dependent phonon renormalization in monolayer MoS2 transistor. Phys. Rev. B 85, 161403 (2012).
Balocchi, A. et al. Full electrical control of the electron spin relaxation in GaAs quantum wells. Phys. Rev. Lett. 107, 136604 (2011).
Koralek, J. D. et al. Emergence of the persistent spin helix in semiconductor quantum wells. Nature 458, 610–614 (2009).
Acknowledgements
The authors thank B. Spivak for helpful discussions. This work is mainly supported by the US DoE, BES, Division of Materials Sciences and Engineering (DE-SC0008145), and device fabrication is partially supported by the NSF (DMR-1150719). A.J. was supported by the NSF Graduate Research Fellowship (DGE-0718124). G-B.L. and W.Y. were supported by the Research Grant Council of Hong Kong (HKU 706412P). W.Z. and D.X. were supported by US DoE, BES, Division of Materials Sciences and Engineering. D.C. and Z.F. were supported by the DoE BES (DE-SC0002197). The DFT calculations were performed at the National Energy Research Scientific Computing Center supported by the DoE Office of Science. Device fabrication was performed at the University of Washington Micro Fabrication Facility and NSF-funded Nanotech User Facility.
Author information
Authors and Affiliations
Contributions
All authors discussed the results and made critical contributions to the work.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Supplementary Information
Supplementary Information (PDF 737 kb)
Rights and permissions
About this article
Cite this article
Wu, S., Ross, J., Liu, GB. et al. Electrical tuning of valley magnetic moment through symmetry control in bilayer MoS2. Nature Phys 9, 149–153 (2013). https://doi.org/10.1038/nphys2524
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/nphys2524
This article is cited by
-
Role of active edge sites of atomically thin CVD-grown MoS2 layers on the enhanced visible-light photocatalytic activity
Journal of Materials Science: Materials in Electronics (2024)
-
Investigating valley-dependent current generation due to asymmetric energy dispersion for charge-transfer from a quantum dot to single-walled carbon nanotube
Scientific Reports (2023)
-
Uncovering spin-orbit coupling-independent hidden spin polarization of energy bands in antiferromagnets
Nature Communications (2023)
-
Every-other-layer dipolar excitons in a spin-valley locked superlattice
Nature Nanotechnology (2023)
-
Energy Levels of Quantum Dots in Monolayer of Molybdenum Disulfide MoS\(_2\)
International Journal of Theoretical Physics (2023)