Abstract
Moiré superlattices of semiconducting transition metal dichalcogenides enable unprecedented spatial control of electron wavefunctions, leading to emerging quantum states. The breaking of translational symmetry further introduces a new degree of freedom: high symmetry moiré sites of energy minima behaving as spatially separated quantum dots. We demonstrate the superposition between two moiré sites by constructing a trilayer WSe2/monolayer WS2 moiré heterojunction. The two moiré sites in the first layer WSe2 interfacing WS2 allow the formation of two different interlayer excitons, with the hole residing in either moiré site of the first layer WSe2 and the electron in the third layer WSe2. An electric field can drive the hybridization of either of the interlayer excitons with the intralayer excitons in the third WSe2 layer, realizing the continuous tuning of interlayer exciton hopping between two moiré sites and a superposition of the two interlayer excitons, distinctively different from the natural trilayer WSe2.
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Introduction
Design and control of symmetries can lead to symmetry-protected states that are promising to revolutionize the field of quantum materials. For example, breaking the inversion symmetry or time-reversal symmetry can lead to Weyl semimetals1. The inversion symmetry breaking in transition metal dichalcogenides (TMDCs) gives rise to a valley degree of freedom that is promising for valleytronics and quantum information science based on valley-spin2, which can be accessed through chiral light.
The recent emergence of semiconducting TMDC moiré superlattices3,4,5,6,7,8,9, which are constructed through twisted TMDCs with a lattice mismatch or twist angle, enables spatial control of the excitons in two-dimension (2D) with the tunable periodicity of 1–10 nm and ushers in unprecedented opportunities in engineering electrons and excitons, leading to intriguing correlated electronic states3,6,10,11,12,13,14,15, the array of quantum emitters, and correlated exciton states resulting from flat excitonic band16,17,18.
Translation symmetry breaking in TMDC moiré superlattices introduces a new degree of freedom: moiré sites, the high symmetry points in a moiré supercell, which can be local energy minima and act as quantum dots5,19,20 that can confine electrons and excitons, as schematically shown in Fig. 1c. In addition, these high symmetry points are protected by the three-fold rotation symmetry and possess the unique valley degree of freedom through the pseudo angular momentum conservation4,19. As a result, coupling and hybridization of these high symmetry points will usher in new venues toward quantum information storage and processing. However, unlike the energy degeneracy of different valleys (K and K’), the energy barrier between different moiré sites (on the order of 10 s’ meV), along with their spatial separation, greatly suppresses the direct coupling between these moiré sites.
Here, we demonstrate the superposition between two different moiré sites by introducing a layer degree of freedom to the TMDC moiré superlattice. It is well known that the two neighboring layers of 2-H TMDC flakes, due to the intralayer inversion symmetry breaking, possess a layer degree of freedom that acts as pseudospins alternating in odd and even layers2,21. In an angle-aligned trilayer WSe2/monolayer WS2 heterojunction (3L WSe2/1L WS2), new types of interlayer excitons emerge, with holes residing in the first WSe2 layer either trapped in moiré A or B site (Fig. 1c)5, and electrons with the same pseudospin residing in the third WSe2 layer. In particular, we find that these two interlayer excitons can hybridize through coupling with the intralayer excitons in the third WSe2 layer. The resulting hybridized exciton inherits both the large oscillator strength from the intralayer excitons and the sensitive electric field dependence from the moiré interlayer excitons7,22,23,24. More interestingly, by applying an electric field, we can drive the transition between the two interlayer moiré excitons’ hybridization with the intralayer exciton in the third WSe2 layer, enabling the continuous tuning of hopping of the interlayer exciton from 100% at one moiré site to 100% at the other, which is otherwise suppressed. In between the transition points, we obtain an excitonic complex that is the superimposition of the interlayer excitons that are otherwise localized at moiré A and B sites.
Results and Discussions
Gate dependence of reflectance contrast
The schematic of the 3L WSe2/1L WS2 moiré heterojunction is shown in Fig. 1a, which is fabricated into a dual-gated device structure in which the doping and electric field can be independently controlled. We also fabricated a device of a dual-gated 2-H phase trilayer WSe2 (3L WSe2) (schematically shown in Fig. 1b) for the control study.
The doping-dependent optical reflectance contrast spectra of the 3L WSe2/1L WS2 heterojunction device are shown in Fig. 2e, which is evidently different from that of the natural trilayer (3L) WSe2 device (Fig. 2f). The most pronounced resonance for the natural trilayer WSe2 (Fig. 2f) is the intralayer exciton resonance XA, which is at ~ 1.70 eV at zero doping, redshifted compared to the A exciton resonance in monolayer WSe2 (~1.73 eV)25. XA is redshifted linearly for both n and p doping in a symmetric fashion, with a slope of ~1.3 meV/1012 cm−2. \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\) are the interlayer excitons with the hole and electron separated in the first and third WSe2 layer, which have two degenerate modes as schematically shown in Fig. 2c and are named as \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\) (“+” and “−” denote the direction of the dipole moment in the sample coordinate. The direction of the positive electric field or dipole moment is defined as from the top gate to the back gate in 3 L WSe2, and from WSe2 to WS2 in 3L WSe2/ 1 L WS2.). \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{2{{{{{\rm{s}}}}}}}\) is the 2s state of the \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\). The natures of \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{2{{{{{\rm{s}}}}}}}\) become obvious in our later discussion of the electric field dependent reflectance contrast spectra. Zoom-in of Fig. 2f with enhanced contrast is plotted in Fig. S2 to show \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{2{{{{{\rm{s}}}}}}}\) more clearly. Accompanying XA is a less pronounced resonance XA’ with a larger slope (2.7 meV/1012 cm−2). XA’ is likely the exciton resonance of the middle (second) layer WSe2 and is not the focus of this work (see detailed discussion in Supplementary Section 14).
In the optical reflectance contrast spectra of 3L WSe2/1L WS2 moiré heterojunction (Fig. 2e), there is an exciton resonance \(({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}})\) located at the lower energy side of XA (~1.667 eV), which is only observable in angle-aligned 3L WSe2/1L WS2 heterojunctions but absent in heterojunctions with large twist angles (See supplementary section 10 for detailed discussion). \({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}}\) is the previously discovered moiré intralayer exciton peak in the first layer WSe2 interfacing WS2, with the exciton trapped at the moiré A site. The doping dependence of \({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}}\) clearly show the signature of the correlated insulating states at the filling factor of 1 and −1, corresponding to one electron and one hole per moiré superlattice, which was discussed in our previous publication26. On the p-doping side, the exciton resonances of XA and XA’ are labeled as such due to their similar behaviors compared with that from the trilayer WSe2 (Fig. 2f), with a redshift slope of 1.0 and 2.1 meV/1012 cm−2, respectively. The n-doping side is different because the electrostatically introduced electrons are in the WS2 layer instead of the WSe2 layers due to the type II alignment, leaving the WSe2 layers charge-neutral. We identify the XA and XA’ in the n-doping side through their slopes as well, 1.0 and 2.1 meV/1012cm−2, respectively, the same as those in the p-doping region. The abrupt blueshift of the XA in the n-doping side (starts at n > 1 and resonant energy around 1.725 eV) is likely due to the built-in electric field on WSe2 layers arising from the electron accumulation in WS2. We leave the related discussion in Supplementary Information Section 15. The focus of our work here is on the interlayer excitons within the 3L WSe2 of the 3L WSe2/1L WS2 moiré heterojunction, with their schematics shown in Fig. 2a, b. The \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\) branch is visible and pronounced at the blue arrow in Fig. 2e, partially because it hybridizes with intralayer excitons and gains some oscillator strength but also because it retains the extended nature of interlayer excitons, hence sensing dielectric environment change associated with the Mott insulator transition at filling of one electron per moiré superlattice (n = 1). The nature of both resonances are revealed in our later discussion of the electric field dependence study.
Interlayer hybridized excitons in 3L WSe2
The electric field-dependent reflectance contrast spectra of the trilayer WSe2 device is shown in Fig. 3a, which is symmetric about the electric field due to its symmetric structure. The most noticeable feature is the “cross” pattern originating from the electric field evolution from interlayer exciton \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\). The slope of each branch of the cross is roughly the same. These are arising from the Stark shift of the interlayer exciton \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\), with the two degenerate modes (\({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\)) shifting oppositely under an electric field due to the dipole moment of opposite polarity. The Stark energy shift can be expressed as \(\varDelta E=-edF\), where F is the local electric field, e is the electron charge, and d is the electron and hole separation. We extract the value of d to be about 1.26 nm for both \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\), which is about twice that of interlayer exciton dipole moment in WSe2/WS2 (0.7 nm)7, confirming that the electron and hole of interlayer exciton occupy the two outside WSe2 layers in a natural trilayer WSe2.
The level avoiding at the intralayer exciton A (~1.70 eV) in Fig. 3a arises from the hybridization of the interlayer exciton and intralayer exciton. In the 2H trilayer WSe2, there is significant tunneling of holes between the first and third layer WSe2 as they have the same valley-layer pseudo spin, allowing the hybridization of the interlayer excitons with the intralayer excitons in either the first or third WSe2 layer27, as schematically shown in Fig. 3d. This hybridization can be well captured by a coupled two-level system, which is given by the following Hamiltonian in the basis of intralayer exciton and interlayer exciton:
where \({X}_{a}\) is the energy of the intralayer exciton, \({X}_{i}(F)\) is the energy of the interlayer exciton at a given electric field F, Δ is the coupling strength (see Supplementary Information Section 13 for details).
Take the positive electric field (direction defined in Fig. 3d) scenario as an example (Fig. 3c): a linearly dispersed interlayer exciton \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\) (white dotted line in Fig. 3c) and a non-dispersed intralayer exciton XA (black dotted line) can be used to well fit the observed hybridized spectra (red and blue dashed lines). From the fitting, we extract the coupling strength to be 10.7 ± 0.3 meV, larger than the linewidth of the hybridized exciton (~ 9.0 ± 0.3 meV). The scenario of the negative electric field is similar, where the other interlayer exciton mode, \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\), hybridizes with the intralayer exciton (XA) when the energy of the two excitons is tuned to resonance via the electric field. It is worth noting that we ignore the conduction band hybridization of the first and third layer WSe2, which is theoretically predicted to be nonzero but orders of magnitude smaller than the holes27. The neglection of the conduction band hybridization is also justified by the electric-field-dependent reflectance contrast spectra of 3 L WSe2/ 1 L WS2, which is asymmetric about positive and negative electric fields (later discussion of Fig. 4).
The additional level avoiding at the energy around 1.79 eV in Fig. 3a is due to the hybridization of the interlayer exciton \(({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}})\) with the 2s state of intralayer A exciton (Fig. 3a and Fig. S4a, b). The second level avoiding at higher energy (~1.80 eV) is due to the hybridization of the excited state of the interlayer exciton \(({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{2{{{{{\rm{s}}}}}}})\) and 2s of the A exciton, which we enhance the contrast and show in Fig. S4a, b. It is interesting to note that the energy difference between the ground state and 2s of interlayer exciton \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\) is about 51 meV, smaller but at the same order of magnitude compared with the energy difference between 2s and 1s of A exciton for trilayer WSe2 (~95 meV, Fig. S4a, b), suggesting the strongly bound nature of the interlayer exciton \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}\). All these hybridization features are absent in a dual-gated nature bilayer WSe2 (Fig. S8), which is AB stacked with two layers of different layer pseudospin, further confirming our interpretation. The electric-field-dependent reflectance contrast spectra of a 4 L WSe2 device (Fig. S7) show similar hybridization features but with two “crosses” slightly shifted in energy, about 10 meV. According to the interpretation of the 3 L WSe2 data, these two crosses are the two types of interlayer excitons from the 1st and 3rd layer WSe2 and the 2nd and 4th layer WSe2, which slightly shift in energy due to possible dielectric environment differences28,29.
Hybridized Excitons across Moiré States in 3 L WSe2/ 1 L WS2
We now turn to the study of the electric field-dependent reflectance contrast spectra of the 3 L WSe2/ 1 L WS2 moiré heterojunction, shown in Fig. 4c. The negative electric field side has some similarity compared with that from trilayer WSe2, while the positive electric field side is significantly different. More specifically, the hybridized spectrum on the positive electric field side involves three exciton branches: two dispersive (white dotted lines in Fig. 4e) and one non-dispersive (black dotted line in Fig. 4e) branch. The necessity of involving three exciton branches is also obvious from the derivative of Fig. 4e with respect to the electric field, as shown in Fig. S3d. The two dispersive excitons have a similar slope for the Stark shift, translating to electron and hole separations of 1.313 ± 0.004 nm and 1.609 ± 0.004 nm (fitting details in Supplementary Information Section 13). Therefore, they are the interlayer excitons, similar to \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\) in the natural trilayer WSe2, with the hole in the first WSe2 layer interfacing WS2 and the electron in the third WSe2 layer away from the interface. The two different interlayer excitons stem from the moiré coupling modified valence band of the first WSe2 layer. As schematically shown in Fig. 4a and b, the moiré modulation folds the valence band of the first WSe2 layer into moiré minibands. The two interlayer excitons correspond to holes occupying the two moiré minibands located at different moiré sites20, which effectively behave as two spatially separated quantum dots. Each of them is located at an energy minimum at a high symmetry point within the moiré unit cell, which we call moiré A and B sites, respectively. We thus label these two interlayer excitons as \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+\,({{{{{\rm{A}}}}}})}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+\,({{{{{\rm{B}}}}}})}\). Since the WS2 and first WSe2 layer are aligned at 60 degrees (H stacked) as determined by the second harmonic generation (SHG) spectra (Fig. S5), the moiré A and B sites correspond to the \({H}_{h}^{h}\) and \({H}_{h}^{X}\) stacking configurations shown in Fig. 4b. The energy separation of the two interlayer excitons at zero electric field, 69 meV, represents the energy difference between the top two moiré minibands, if we ignore the difference in exciton binding energy. This value is consistent with the energy difference between the intralayer excitons trapped at moiré A and B sites in the WSe2/WS2 moiré superlattice, ~53 meV26. The remaining non-dispersive branch corresponds to the intralayer exciton, XA, with both hole and electron in the third WSe2 layer. Therefore, \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+\,({{{{{\rm{A}}}}}})}\), \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+\,({{{{{\rm{B}}}}}})}\), and XA hybridize by sharing the electron in the third WSe2 layer. The above picture of hybridization involving two moiré interlayer excitons are confirmed by a control device (D4) of 3 L WSe2/ 1 L WS2 in the dual-gate configuration, with an intentionally misaligned angle (20-degree) between WSe2 and WS2 layers. The electric-field-dependent reflectance contrast spectra (Fig. S11) indeed become symmetric about the electric field and similar to that of natural 3 L WSe2, and they show no signs of interlayer moiré excitons (\({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+\,({{{{{\rm{A}}}}}})}\) and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+\,({{{{{\rm{B}}}}}})}\)).
It is worth noting that direct tunneling between moiré A and B sites is suppressed due to the energy barrier, their spatial separation, and different stacking symmetry. Therefore, a direct hybridization between these two sites is difficult to achieve, unlike the degenerate valley-spin bands in TMDCs. However, with the assistance from the mobile intralayer exciton in the third WSe2 layer, hybridization of moiré A and B sites is realized, and we can controllably tune the interlayer excitons \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\) between moiré A and B sites. In fact, the hybridized exciton notated with the cyan dashed line is a mixture of interlayer excitons localized at the moiré A site and B site, with the probability tunable from 100% at A to 100% at B site by controlling the electric field (Fig. 4f).
On the negative electric field side, the interlayer exciton involved in the hybridization is \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\), with the hole in the third layer WSe2 not experiencing the moiré modulation. Meanwhile, the intralayer exciton in the 1st WSe2 layer is modified by the moiré potential to have a lower energy of ~ 1.667 eV and is trapped at the moiré A site, which is labeled as \({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}}\). As a result, hybridization occurs between \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\) and \({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}}\). Their coupling strength is extracted to be 11.4 ± 0.1 meV. The interlayer exciton \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\) can also couple to the other moiré excitons from the 1st layer WSe2, which contributes to the weak features in Fig. 4 and are shown with enhanced contrast in Fig. S4c, d.
The asymmetry of Fig. 4c between the n- and p-doping sides further justifies our neglection of conduction band hybridization: \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{-}\) near hybridization region d in Fig. 4c goes directly through XA, and \({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\) near region e goes directly through \({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}}\), with neither showing level avoiding. If the conduction band hybridization is significant, we should observe the hybridization of two interlayer excitons (due to moiré modulated conduction bands) and XA. Similarly, the interlayer exciton from region e (\({{{{{{\rm{IX}}}}}}}_{3{{{{{\rm{L}}}}}}}^{+}\)) in Fig. 4c should hybridize with \({{{{{{\rm{X}}}}}}}_{{{{{{\rm{M}}}}}}}^{{{{{{\rm{I}}}}}}}\). We include a detailed discussion in Supplementary Information Section 16.
In summary, we have demonstrated a strategy to realize continuous tuning of interlayer exciton hopping between different moiré sites in 3 L WSe2/ 1 L WS2 moiré superlattices. These additional degrees of freedom enable the formation of a tunable honeycomb lattice of excitons with exciting opportunities for engineering new quantum states. For example, considering the large spin-orbit coupling in TMDCs, the continuous tuning of the hopping can be potentially exploited for constructing Dirac and Weyl modes of excitons, as well as the topologically protected edge states connecting these modes19. Our demonstration of the superposition of excitons across the different moiré sites also inspires new venues of quantum information processing and harnessing the new moiré site degree of freedom for twistronics.
Methods
Sample Fabrication
We used the same dry pick-up method30 as reported in our earlier work to fabricate TMDC heterostructures17,26. The gold electrodes are pre-patterned on the Si/SiO2 substrate. The monolayer TMDC flakes, BN flakes, and few-layer graphene (FLG) flakes are exfoliated on silicon chips with 285 nm thermal oxide. The thickness of BN flakes was determined by atomic force microscopy (AFM). The layer numbers of WSe2 flakes were identified by optical contrast with the assistance of second-harmonic generation (SHG). Top BN and bottom flakes with equal thickness were intentionally used for devices D1, D2, and D3. The polycarbonate (PC)/ polydimethylsiloxane (PDMS) stamp was used to pick up TMDC monolayer and other flakes sequentially. The alignment of each layer is achieved under a home-built microscope transfer stage with the rotation controlled with an accuracy of 0.02 degrees. The PC is then removed in the chloroform/isopropanol sequence and dried with nitrogen gas. The final constructed devices were annealed in a vacuum (<10−6 torr) at 250 °C for 8 hours.
Optical Measurements
During the optical measurements, a home-built confocal imaging system was used to focus the laser onto the sample (with a beam spot diameter ~ 2 µm) and collect the optical signal into a spectrometer (Princeton Instruments). The reflectance contrast measurement was performed using a supercontinuum laser source (YSL photonics). A relative flat reflectance background R0 was obtained by fitting the reflectance spectrum at high hole-doping level with a polynomial function for each measured spot (see Supplementary Section 11 for details). The reflectance contrast is defined as \(\frac{dR}{R}=\frac{R-\,{R}_{0}}{{R}_{0}}\). The reflectance contrast from device D1 and D2 are added by 0.3 and −0.3 for better presentation in the log scale. All optical spectroscopy measurements were performed at the temperature of 10 K with a Montana cryostat. The polarized SHG measurements were performed with a pulsed laser excitation centered at 900 nm (Ti: Sapphire; Coherent Chameleon) with a repetition rate of 80 MHz and a power of 80 mW. The crystal axes of the sample were fixed. A half-waveplate was placed between the beam splitter and the objective and was rotated to change the polarization angles of both the excitation laser and the SHG signal.
Doping and Electric Field Calculations
The density of carriers introduced by the electrostatic gating is given by \({n}_{e}({n}_{p})={C}_{tg}({V}_{tg}-{V}_{tg}^{0})+{C}_{bg}({V}_{bg}-{V}_{bg}^{0})\), where \({C}_{tg}({C}_{bg})\) are the geometry capacitance of the top gate (back gate) and \({V}_{tg}\,({V}_{bg})\) are the top gate (back gate) voltage. \({V}_{tg}^{0}\) and \({V}_{bg}^{0}\) are the onset gate voltages of the top gate and the back gate, determined experimentally from the regions where the 2s peaks remain visible. The electrical field in the TMDC is given by \(F={\varepsilon }_{BN}/{\varepsilon }_{TMDC}({V}_{tg}/2{d}_{1}-{V}_{bg}/2{d}_{2})\), where \({d}_{1}({d}_{2})\) is the thickness of the top (bottom) BN determined by atomic force microscopy, \({\varepsilon }_{BN}=3.5\) and \({\varepsilon }_{TMDC}=7.2\) are the relative dielectric constants of h-BN and TMDC, respectively31,32.
Data availability
The data in Figs. 1–4 are provided in the source data files. All other data that support the plots within this paper and other findings of this study are available from the corresponding author upon reasonable request. Source data are provided with this paper.
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Acknowledgements
Z.L. and S.-F.S. acknowledge support from NYSTAR through Focus Center-NY–RPI Contract C180117. The device fabrication was supported by the Micro and Nanofabrication Clean Room (MNCR) at Rensselaer Polytechnic Institute (RPI). S.-F. S., D.C., and X.C. also acknowledge the support from NSF Grant DMR-1945420, DMR-2104902, and ECCS- 2139692. Y.-T.C. acknowledge support from NSF under award DMR-2104805. The optical spectroscopy measurements were supported by a DURIP awards through Grant FA9550-20-1-0179 and FA9550-23-1- 0084. S.T. acknowledges DMR-2111812 for materials development, DMR-2206987 for structural characterization and magnetic impurity tests, DMR-2052527 for electronic tests, CMMI-2129412 for structure-performance-property relations, and DOE SC-SC0020653 for initial excitonic characterization. K.W. and T.T. acknowledge support from JSPS KAKENHI (Grant Numbers 19H05790, 20H00354, and 21H05233). Y.S. and C.Z. acknowledge support from NSF PHY-2110212, PHY-1806227, ARO (W911NF17-1-0128), and AFOSR (FA9550-20-1-0220).
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Contributions
S.-F.S. conceived the project. Z.L., D.C. and Y.M. fabricated devices. Z.L. performed measurements. M.B. and S.T. grew the TMDC crystals. T.T. and K.W. grew the BN crystals. S.-F. S., Y.-T.C., Z.L. and D.C. analyzed the data. S.-F. S. supervised the project. S.-F. S. and Y.-T. C. wrote the manuscript with input from all authors.
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Lian, Z., Chen, D., Meng, Y. et al. Exciton Superposition across Moiré States in a Semiconducting Moiré Superlattice. Nat Commun 14, 5042 (2023). https://doi.org/10.1038/s41467-023-40783-z
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DOI: https://doi.org/10.1038/s41467-023-40783-z
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