Introduction

Heterostructures of layered two-dimensional materials exhibit rich transport and optical phenomena. In twisted or lattice-incommensurate heterobilayers (HBLs), laterally modulated van der Waals interactions give rise to spatial variations in the degree of interlayer hybridization on the characteristic length scale of the moiré interference pattern1,2,3,4,5,6. The formation of moiré superlattices has profound effects on the electronic band structure, as evidenced by the emergence of correlated transport phenomena in flat bands of twisted bilayer7,8 and trilayer9,10 graphene, or detected optically in twisted homobilayers11 and aligned HBLs12,13 of transition metal dichalcogenides (TMDs). The latter also exhibit rich moiré signatures in the optical spectra of intralayer14 and interlayer15,16,17,18 excitons formed by Coulomb attraction among layer-locked and layer-separated electrons and holes.

In MoSe2-WSe2 HBL, a prominent representative of TMD heterostacks, the interlayer exciton photoluminescence (PL) is observed well below the intralayer features of monolayer MoSe2 and WSe2 constituents19. The PL energy is consistent with a staggered band alignment20 which separates electrons and holes into the conduction and valence bands of MoSe2 and WSe2, respectively. In accord with layer separation, interlayer excitons exhibit strongly prolonged radiative lifetimes19 and reduced oscillator strength21. Despite numerous experimental and theoretical studies of MoSe2-WSe2 HBLs, the origin of the lowest-energy PL remains a subject of debate22. While the majority of experimental studies interpret the HBL emission in terms of zero-momentum interlayer excitons with K or \(K^{\prime}\) valley electrons and holes in MoSe2 and WSe215,16,19,21,23,24,25,26,27,28,29, others invoke excitons built from hybridized HBL conduction band states at Q pockets30,31,32, located roughly halfway between the center of the first Brillouin zone at Γ and K or \(K^{\prime}\) valleys. Band structure calculations indeed suggest that hybridization of states near Q conduction band and Γ valence band of MoSe2 and WSe2 gives rise to strong energy renormalization upon HBL formation2,33,34 which might turn either QK or QΓ interlayer excitons, composed of electrons at Q and holes at K or Γ, into the lowest-energy states.

Additional complication arises in the presence of moiré effects. In moiré-modulated HBLs, electronic states exhibit valley-contrasting energy shifts upon interlayer hybridization, with states in K and \(K^{\prime}\) valleys being less susceptible to energy-reducing interactions than the conduction band states at Q or the valence band states at Γ. This effect, analogous to the origin of the direct-to-indirect band gap cross-over in TMD monolayers and bilayers35,36,37, should also impact the band structure of HBLs2 yet has been mostly neglected in the context of moiré excitons1,3,4,5,6. Interlayer hybridization is expected to play an even more prominent role in heterotrilayer (HTL) systems with native homobilayers. For the explicit case of MoSe2-WSe2 HTLs, one would expect sizable hybridization effects between the MoSe2 bilayer band edge states at Q and their counterparts in monolayer WSe2, rendering the overall heterostructure an indirect band gap semiconductor.

Results

MoSe2-WSe2 heterobilayer and heterotrilayer in cryogenic spectroscopy

Motivated by the contrasting behavior anticipated for momentum-direct and indirect band edge interlayer excitons in MoSe2-WSe2 HBL and HTL, we performed optical spectroscopy studies of the corresponding moiré heterostructures on the same sample. The heterostack was connected to a charge-reservoir for voltage control of capacitive doping. To this end, a MoSe2 crystal with monolayer and bilayer regions was stacked onto a WSe2 monolayer by dry viscoelastic stamping38, encapsulated from both sides by hexagonal boron nitride (hBN) and stamped into contact with a gold electrode with gate voltage referenced against a grounded layer of silver capped by SiO2 (Supplementary Note 1). The MoSe2 crystal with a native bilayer region in 2H or AA′ stacking was twisted away from parallel R-type alignment by about 4 with respect to the WSe2 monolayer. At such relatively large angles, we expect the moiré heterostructure to be robust against reconstruction39,40,41 and thus to contrast previous studies of MoSe2-WSe2 HBLs carefully aligned for zero twist angle in R-type stacking24,28 as well as moiré-free HBLs obtained from chemical vapor deposition with lattice-mismatch relaxation and inherent alignment21,23.

Cryogenic PL and differential reflectivity (DR) spectra of the HBL and HTL regions at 3.2 K and zero gate voltage are shown in Fig. 1a, b, respectively. The DR features in the spectral range between 1.55 and 1.75 eV are consistent with absorption characteristics of neutral intralayer excitons, and the vanishingly small trion feature in Fig. 1a indicates operation close to charge-neutrality (Supplementary Note 1). Whereas the two dominant DR peaks of the HBL spectrum in Fig. 1a essentially reflect the respective MoSe2 and WSe2 monolayer transitions around 1.6 and 1.7 eV, the HTL spectrum in Fig. 1b is different. Compared to the HBL spectrum, it exhibits a red-shift of the WSe2 intralayer exciton peak by 8 meV because of Coulomb screening by the additional MoSe2 layer, and a rich structure around the MoSe2 absorption peak with possible contributions from interlayer excitons of bilayer MoSe242 as well as moiré miniband effects6 in the twisted HTL.

Fig. 1: Cryogenic photoluminescence and differential reflectivity spectra of MoSe2-WSe2 heterobilayer and heterotrilayer.
figure 1

a, b Photoluminescence (black and gray) and differential reflectivity (blue and dark cyan) spectra of twisted HBL and HTL MoSe2-WSe2 at 3.2 K. The luminescence was excited with linearly polarized excitation laser at 1.85 eV and scaled in intensity below 1.47 eV by a factor of 5 in both graphs.

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Within the same energy range, the cryogenic PL is consistently dominated by intralayer excitons. Remarkably, the intralayer MoSe2 and WSe2 peaks in the HBL spectrum of Fig. 1a are nearly completely quenched in the HTL spectrum of Fig. 1b, indicating for the latter drastically suppressed hot luminescence due to enhanced population relaxation into lowest-energy interlayer exciton levels. This observation is in accord with the theoretical prediction of increased charge transfer efficiency via hybridized Q and Γ states in heterostructures2.

Another striking difference in the PL of the heterostacks is evident in the spectra of Fig. 1a, b for interlayer excitons, with PL emission below 1.40 and 1.33 eV from HBL and HTL regions, respectively. The PL characteristics depend on the heterostack position, as confirmed by lateral displacement of the sample with respect to fixed confocal excitation and detection spots. Upon transition from the HBL to the HTL region, the set of the HTL peaks below 1.35 eV emerges at the expense of the higher-energy HBL peaks with emission energy above 1.35 eV (Supplementary Note 2). At each heterostack site, the overall multi-peak PL structure of HBL and HTL is mostly preserved upon the variation in the gate voltage (Supplementary Note 1) and excitation power down to 300 nW (Supplementary Note 3). Consistent with finite twist angle, the multi-peak PL of the HBL below 1.40 eV, with a peak separation of 30 meV between the two highest energy peaks and 15 meV between other consecutive peaks (Supplementary Note 3), is reminiscent of rich MoSe2-WSe2 moiré spectral features16 rather than of simple spectra from aligned HBLs24,25,26,27,28,29. Remarkably, the HTL PL, with a similar peak spacing of 15 meV, is strikingly similar to the cryogenic PL from native bilayer WSe243 (Supplementary Note 4).

In time-resolved PL, HBL, and HTL PL exhibit similar decay dynamics (Supplementary Note 5). Spectral sampling of the PL decay characteristics indicates the presence of at least three decay channels without conclusive dependence on the emission energy for both HBL and HTL emission. Throughout the spectral band of interlayer excitons, the PL decay exhibits three decay timescales of 3, 12, and 480 ns for HBL and 1, 12, and 300 ns for HTL. For both heterostacks, PL decay was dominated by the slow component (with a weight of 89% and 80% in HBL and HTL, respectively) with contributions of the intermediate (fast) decay channel of 8% and 13% (3% and 7%) to the HBL and HTL emission, respectively. These timescales are in accord with previous studies of MoSe2-WSe2 HBL21,31,44,45 and subject to different and partly competing interpretations.

Theory of excitons in R-stacked MoSe2-WSe2 heterobilayer and heterotrilayer

The differences in the PL spectra of Fig. 1a, b suggest different origins for the interlayer exciton PL in MoSe2-WSe2 HBL and HTL. To provide a basis for the interpretation of our observations, we performed numerical calculations of the band structure and exciton g-factors with density functional theory (DFT) in generalized gradient approximation (Supplementary Notes 6 and 7). Assuming that the twist angle is sufficiently small to employ local band structure approximation4,46, we restrict our analysis to three high-symmetry points of the moiré superlattice in each heterostructure with stackings indicated in Fig. 2a (Supplementary Note 6). Using the band structure results from DFT, we employed the Wannier exciton model in the effective mass approximation47 to calculate the energies of intralayer and interlayer excitons in different spin-valley configurations.

Fig. 2: Theory of excitons in high-symmetry stackings of MoSe2-WSe2 heterobilayer and heterotrilayer.
figure 2

a Schematics of twisted HBL and HTL MoSe2-WSe2 with different high-symmetry stackings. b, c Energy and squared sum of coordinate operator (multiplied by 100 below 1.55 eV) for intralayer and interlayer excitons in HBL and HTL, respectively, calculated for three different stackings. Filled squares, circles, and diamonds denote A'B', AA, and AB', and (A'B')A', (AA)A', and (AB')A' stackings in HBL and HTL, respectively. Empty symbols indicate corresponding HTL excitons with electrons residing in the topmost MoSe2 layer. For zero-momentum KK interlayer excitons (top panels) we indicate the spin configuration by solid and dashed lines for spin-like and spin-unlike states (corresponding to spin-singlet and spin-triplet excitons), and the polarization of the respective exciton emission by red (σ+), blue (σ), and black (in-plane z) colors. The bottom panels show the energy of finite-momentum interlayer excitons in QK (green), QΓ (orange), and KΓ (violet) configurations without direct radiative transitions.

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In the top panels of Fig. 2b, c we show the oscillator strength, essentially determined by the squared modulus of the coordinate operator matrix elements, for direct KK exciton transitions in different R-type stackings of HBL and HTL. For all stackings, interlayer excitons exhibit at least two orders of magnitude lower oscillator strengths than their intralayer counterparts33 with dipolar selection rules in agreement with the group theory analysis of R-type HBL5,21. In accord with previous calculations for HBLs, we find the lowest-energy KK interlayer exciton for A′B′4,33 and energetically higher excitons for AA and AB′ stackings. In all HBL stackings of R-type registry considered here, the lowest KK interlayer exciton is spin-like (i.e., in collinear electron spin orientation of occupied conduction band and unoccupied valence band states, and equivalent to spin-singlet configuration in the electron-hole notation), about 20 meV below its spin-unlike counterpart (or spin-triplet electron-hole pair). In AA stacking, the spin-like state has the largest oscillator strength, whereas for spin-unlike states only the KK exciton in A′B′ stacking has a sizable oscillator strength in agreement with previous DFT results33,34.

For the HTL, our calculations predict an increase in the number of conduction bands associated with lowest-energy excitons due to the additional MoSe2 layer. As such, interlayer KK excitons can be grouped according to the localization of the conduction band electron in one of the MoSe2 layers. For electrons localized on the MoSe2 layer with immediate proximity to WSe2 (full symbols in Fig. 2c), the corresponding interlayer excitons feature similar energies (with a small red-shift due to modified screening) and oscillator strengths as in the HBL system. Additional interlayer states arise from excitons with the electron localized in the upper MoSe2 layer (open symbols in Fig. 2c). Their energetic ordering, with spin-unlike configuration again being lowest, and dipolar selection are identical to KK interlayer excitons in HBLs of H-type registry5,21. However, the corresponding transitions have drastically inhibited oscillator strengths due to a reduced wavefunction overlap between the electron and hole in the topmost MoSe2 and the bottom WSe2 layer and thus should not contribute sizeably to the PL of HTL48. Based on our analysis, we rule out excitons composed of electrons and holes that are locked in distant layers as candidates for bright PL emission in the red-most part of the HTL spectrum.

In addition to KK excitons, our calculations yield the energies of momentum-indirect QK, QΓ, and KΓ excitons (bottom panels of Fig. 2b, c) composed from electrons in Q (or \(Q^{\prime}\)) and K as well as holes at K or Γ. Note that the notion of oscillator strength is meaningless for momentum-indirect excitons without direct radiative decay pathways. The energetic ordering of interlayer excitons with zero and finite center-of-mass momentum differs substantially in HBL and HTL systems: whereas our calculations predict energetic proximity for KK, QK, and KΓ states in HBLs, finite-momentum QK, and QΓ states in HTL are energetically well below the direct KK states, with an energy difference in the order of 200 meV. This trend is well known for monolayer and bilayer TMDs, where the states at K are much less sensitive to the addition of one layer than the states at Q and Γ35,36,37,49. For the HTL, strong interlayer hybridization should result in efficient layer coupling as opposed to layer locking48. The respective experimental signature of enhanced relaxation from intralayer to interlayer exciton states is the strong suppression of the HTL PL around the MoSe2 intralayer resonance at 1.62 eV in Fig. 1b.

Power-dependent PL and degree of circular polarization of MoSe2-WSe2 heterobilayer and heterotrilayer

We find experimental support for our theoretical description of HBL and HTL excitons by probing the PL and the degree of circular polarization (PC) as a function of excitation power. The corresponding results are shown in Fig. 3a–d for HBL and HTL, respectively. Upon increasing excitation power from 0.1 to 100 μW, the HBL spectrum develops a pronounced shoulder above 1.40 eV with vanishing PC (indicated by the dashed black line in Fig. 3a, b). This feature is consistent with hot luminescence from energetically higher states with z-polarized in-plane emission collected by our objective with high numerical aperture and corresponding collection solid angle. Our theory provides spin-unlike and spin-like interlayer excitons in AA and AB′ stacking, respectively, as two potential reservoirs for this emission (z-polarized states in Fig. 2b).

Fig. 3: Power-dependent photoluminescence and degree of circular polarization of MoSe2-WSe2 heterobilayer and heterotrilayer.
figure 3

a, b Photoluminescence spectra and degrees of circular polarization (PC) for twisted HBL MoSe2-WSe2 at 0.1 (black), 10 (brown), and 100 μW (purple) excitation power. c, d Same for HTL MoSe2-WSe2. Dashed lines indicate hot luminescence at the higher-energy side of the interlayer exciton spectrum with zero (black) and finite (red) PC.

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In contrast, the brightest HBL peaks between 1.32 and 1.40 eV with a positive degree of circular polarization are present down to lowest excitation powers. They are consistent with spin-like (spin-unlike) KK interlayer excitons in AA (A′B′) stacking (states in Fig. 2b with σ+ polarization). As we observe no sign reversal in PC as expected for the lowest-energy spin-like KK interlayer exciton in A′B′ stacking (state in Fig. 2b with σ polarization) and reported previously for structured HBL PL16, strong contribution from A′B′ stacking is unlikely in our sample. This implies that AA domains dominate the HBL PL in rigid moiré supercells, although A′B′ regions should be at least of comparable size39. In the presence of reconstruction, one would expect predominance of energetically favored A′B′ and AB′ triangular domains of comparable area39,40,50. Without reconstruction, on the other hand, a reversal in the energetic ordering of AA and A′B′ interlayer excitons at finite twist angles, as predicted recently by theory for R-type MoSe2-WSe2 heterostructures51, would satisfactorily explain the observation.

According to our theory analysis, the structure of HTL PL is of different origin. The HTL data in Fig. 3c, d reveal KK interlayer exciton states through power-activated hot luminescence at the higher-energy side of the spectrum with finite circular degrees of polarization (indicated by the dashed red lines in Fig. 3c, d). The respective emission peaks at 1.35 and 1.38 eV can be ascribed to KK interlayer excitons with σ+ polarization in (A′B′)A′ or (AA)A′ stackings (red-colored states in Fig. 2c). Similar to the HBL, the HTL spectrum exhibits upon 100 μW excitation power an additional higher-energy hot luminescence peak at 1.43 eV with vanishing PC (black dashed line in Fig. 3c, d). The respective candidate from theory is the KK reservoir in (AB′)A′ stacking with z-polarized transition, as the (AA)A′ interlayer excitons with the same selection rules are dismissed due to vanishingly small oscillator strength (black-colored states in Fig. 2c). On the low energy side, the peaks around 1.30 eV below the energy of KK hot luminescence can result as phonon sidebands from momentum-dark QK or QΓ interlayer exciton reservoirs (states in the bottom panel of Fig. 2c shown in green and orange). Without removing the ambiguity in the assignment of the lowest-energy reservoir to QK or QΓ, this scenario explains the similarity in the spectral shape of HTL PL and the PL of native bilayer WSe2 originating from momentum-indirect excitons43,52.

Magneto-luminescence of MoSe2-WSe2 heterobilayer and heterotrilayer

Additional insight into the origin of HBL and HTL peaks is obtained from magneto-luminescence experiments in Faraday configuration and theoretical analysis. The experimental dispersion of the PL peaks in external magnetic field applied perpendicular to the heterostructure is shown in Fig. 4. The solid black lines indicate linear energy shifts recorded for σ+ and σ circularly polarized PL as a function of magnetic field. From this set of data, we determine the respective g-factors using the relation ΔE = gμBB, where ΔE is the energy splitting between σ+ and σ polarized peaks proportional to the interlayer exciton g-factor, μB is the Bohr magneton, and B is the magnetic field. For the HBL, the extracted g-factors range between −4.2 and −6.2 with the same sign as for WSe2 intralayer excitons, whereas the HTL peaks exhibit g-factors between −12 and −13. In combination with observations described above and ab-initio calculations of g-factors for various spin-valley configurations of interlayer excitons in high-symmetry HBL and HTL stackings (Supplementary Note 7), these values suggest the following picture for MoSe2-WSe2 HBL and HTL stacks twisted away from ideal R-type registry.

Fig. 4: Valley Zeeman shift of interlayer excitons in MoSe2-WSe2 heterobilayer and heterotrilayer.
figure 4

a, b Magneto-luminescence of twisted HBL MoSe2-WSe2 for linear excitation and σ+ (red) and σ (blue) circularly polarized detection, respectively. c, d Same for HTL MoSe2-WSe2. The solid lines show magneto-induced energy shifts of HBL and HTL peaks with g-factors (from high to low energy) and error bars from least-square linear fits of − 6.2 ± 0.8, − 4.2 ± 0.8, and − 5.5 ± 0.8, and − 12.0 ± 2.0, − 12.0 ± 0.8, and − 13.0 ± 0.8, respectively.

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Discussion

First, we note that the experimental g-factors determined for the HBL peaks from the data of Fig. 4a, b (−6.2 ± 0.8, −4.2 ± 0.8, and −5.5 ± 0.8) are consistent with previous studies of aligned MoSe2-WSe2 heterostructures in R-type registry with absolute values in the range from 6.1 to 8.515,24,28. They clearly contrast the interlayer exciton g-factor values between 15 and 16 in HBLs of H-type registry15,26,29,53. For the respective KK interlayer excitons in R-type HBLs, our calculations (Supplementary Note 7) predict an absolute g-factor value close to 6 and opposite signs for the degrees of circular polarization in AA and A′B′ stackings (with negative and positive PC, respectively), in agreement with a similar theoretical analysis of interlayer exciton g-factor values and signs54,55.

We proceed by discussing possible origins of the structured HBL emission. In the framework of moiré excitons, multi-peak PL has been ascribed to interlayer exciton states confined in moiré quantum wells16,45. Assuming that finite twist indeed reverses the energetic ordering of interlayer excitons in A′B′ and AA stackings51, the pronounced peaks of HBL PL below 1.40 eV with positive PC and negative g-factors in the order of −6 would correspond to quantum well states of zero-momentum KK moiré excitons in AA stacked regions. This interpretation, however, is only plausible if the redistribution of interlayer exciton population among moiré quantum well sub-bands is bottlenecked. In the presence of population relaxation and thermal redistribution on timescales of the order or below 100–300 ns (longest decay components in PL), one would expect the PL from quantum well excited states to disappear or at least to diminish in intensity due to insufficient exciton population at low excitation powers and low temperature. Instead, we always find the highest energy peak to exhibit the highest intensity down to lowest excitation powers. An alternative interpretation invokes KK interlayer excitons trapped in disorder potentials. Within this scenario, the highest energy peak would stem from KK excitons in AA stacked regions decaying via their respective σ+ polarized radiative channel on the timescale of a few nanoseconds, whereas lower energy peaks with similar g-factors and PC would reflect the respective defect-bound states with prolonged lifetimes. This scenario, however, is in conflict with the observation of spectrally independent PL decay, dismissing defect-trapped interlayer excitons with reduced energy as the primary source of the structured PL. The scenario of an energetically homogeneous distribution of localization by disorder over the entire spectral emission window seems even less plausible.

Finally, the multi-peak structure of HBL PL can be attributed to the joint emission from zero-momentum and finite-momentum interlayer exciton reservoirs21,31. In addition to spin-like KK excitons with a g-factor of 6, our theory identifies spin-like KΓ and spin-unlike \(Q^{\prime} {{\Gamma }}\) with respective g-factors of 4 and 5 as candidates for the lower-energy HBL peaks. Note that theory finds these states in close energetic proximity to spin- and momentum-bright KK interlayer excitons (Fig. 2b). In this framework, the corresponding HBL peaks would qualify as phonon sidebands of KΓ or \(Q^{\prime} {{\Gamma }}\) (or both), and the peak spacings of 30 and 15 meV would reflect the energies of optical and acoustic phonons, or higher-order combinations thereof21,43. This, however, holds only for staggered A′B′ and AB′ stackings that favor energy-reducing layer hybridization among the conduction band states around Q and \(Q^{\prime}\) and the valence band states in the center of the Brillouin zone at Γ. In contrast, hybridization is less effective in AA stacked regions, upshifting the energies of KΓ and \(Q^{\prime} {{\Gamma }}\) manifolds away from KK interlayer and towards intralayer excitons of MoSe2 and WSe2 (two highest energy states in the bottom panel of Fig. 2b). Remarkably, this setting predicts the contributions of zero-momentum and finite-momentum interlayer excitons to HBL PL to stem from different stackings and thus from spatially distinct reservoirs. Consequently, the two-dimensional landscape of lowest-energy moiré excitons would thus be shaped by momentum-direct and indirect states residing in spatially separated domains of different stackings.

The scenario is more simple for HTL PL with finite-momentum excitons being lowest in energy. For the peaks of Fig. 4c, d, the absolute values of g-factors of about 12 take momentum-direct KK interlayer excitons as well as momentum-indirect reservoirs KΓ and QΓ out of the picture. Among the former, dipole-active KK states disqualify due to their g-factor of ~6, and KK spin-like (spin-unlike) configurations formed by the electron in the lower (upper) MoSe2 layer with theoretical g-factors between 11 and 13, as well as the respective \(K^{\prime} K\) counterparts with similar g-factors, are dismissed due to higher energies and thus negligibly small exciton populations. The latter momentum-indirect KΓ and QΓ states exhibit only small g-factors because of the vanishing valley Zeeman term in the Γ valley. By exclusion, the experimentally observed g-factors identify spin-like QK and spin-unlike \(Q^{\prime} K\) interlayer excitons with theoretical g-factors of ~10 and 14 as the only reasonable sources for the HTL PL peaks in the form of phonon sidebands.

From the perspective of moiré exciton energy landscape governed by interlayer hybridization, lowest-energy HBL and HTL excitons should not differ in their spin-valley composition. Our analysis, however, suggests spin-like KΓ or spin-unlike \(Q^{\prime} {{\Gamma }}\) states in HBL, and spin-like QK or spin-unlike \(Q^{\prime} K\) states in HTL as lowest-energy manifolds. This controversy indicates that effects beyond hybridization have to be taken into account: the interplay of laterally modulated strain in moiré landscapes with opposite energy shifts for K versus Q and Γ valleys56, and the combined piezoelectric and ferroelectric effects in the order of tens of meV51 acting differently on interlayer excitons of distinct spin-valley configurations can reorder the hierarchy of energetically proximal interlayer exciton states.

In conclusion, our experimental and theoretical study of excitons in twisted MoSe2-WSe2 HBL and HTL of R-type registry promote a complex picture of HBL PL. It is consistent with radiative recombination of zero-momentum KK interlayer excitons and phonon-assisted emission from momentum-indirect reservoirs residing in spatially distinct regions of high-symmetry stackings. In contrast, the emission from the respective HTL system is entirely governed by phonon-assisted decay of momentum-dark QK or \(Q^{\prime} K\) interlayer excitons. We base our conclusions on extensive optical spectroscopy experiments and calculations of the band structures, exciton states and g-factors for MoSe2-WSe2 HBL and HTL close to R-type registry. On these specific realizations of MoSe2-WSe2 heterostacks, our results highlight the primary role of moiré-modulated interlayer hybridization for the relaxation and formation of excitons in twisted van der Waals heterostructures with increasing layer number and structural complexity. Despite the extensive work presented here, a complete understanding of the rich phenomena observed in TMD heterostructures of different registries and alignment angles will require more efforts in experiment and theory to include piezoelectric and ferroelectric effects as well as strain at a detailed, quantitative level, and in the presence of reconstruction effects.

Methods

The field-effect device based on a MoSe2-WSe2 heterostructure was fabricated by hot pick-up technique38. First, a layer of hBN was picked up, followed by MoSe2 with ML and BL regions, a ML of WSe2 and a capping layer of hBN. The heterostack was subsequently placed in contact to a gold electrode that was deposited on a silver-coated glass substrate with a SiO2 capping layer of 60 nm. PL and DR experiments were performed in a home-built cryogenic microscope. The sample was mounted on piezo-stepping and scanning units (attocube systems, ANPxy101, ANPz101, and ANSxy100) for positioning with respect to a low-temperature objective (attocube systems, LT-APO/LWD/NIR/0.63, or LT-APO/NIR/0.81). The microscope was placed in a dewar with an inert helium atmosphere at a pressure of 20 mbar and immersed in liquid helium at 4.2 K or operated at 3.2 K in a closed-cycle cryostat (attocube systems, attoDRY1000) equipped with a solenoid for magnetic fields of up to ±9 T. DR experiments were performed with a wavelength-tunable supercontinuum laser (NKT, SuperK Extreme, or SuperK Varia), also used for PL excitation around 633 or 715 nm with repetition rates down to 2 MHz. For continuous-wave measurements, the PL was excited with a laser diode at 635 nm or a HeNe laser, spectrally dispersed by a monochromator (Roper Scientific, Acton SP 2750, SP 2558, or Acton SpectraPro 300i) and recorded with a nitrogen-cooled silicon CCD (Roper Scientific, PyLoN, or Spec-10:100BR) or thermo-electrically cooled CCD (Andor iDus). Time-resolved PL was detected with an avalanche photodiode (Excelitas SPCM-AQRH) and correlated with a single photon counting system (PicoQuant, PicoHarp 300).