Abstract
Miniaturized spectrometers are of immense interest for various on-chip and implantable photonic and optoelectronic applications. State-of-the-art conventional spectrometer designs rely heavily on bulky dispersive components (such as gratings, photodetector arrays, and interferometric optics) to capture different input spectral components that increase their integration complexity. Here, we report a high-performance broadband spectrometer based on a simple and compact van der Waals heterostructure diode, leveraging a careful selection of active van der Waals materials- molybdenum disulfide and black phosphorus, their electrically tunable photoresponse, and advanced computational algorithms for spectral reconstruction. We achieve remarkably high peak wavelength accuracy of ~2 nanometers, and broad operation bandwidth spanning from ~500 to 1600 nanometers in a device with a ~ 30×20 μm2 footprint. This diode-based spectrometer scheme with broadband operation offers an attractive pathway for various applications, such as sensing, surveillance and spectral imaging.
Similar content being viewed by others
Introduction
Optical spectrometers, which analyze the spectral contents of light, are cornerstone instruments in a wide variety of application fields ranging from fundamental scientific research to industrial inspections1,2. Conventional spectrometers are bulky and costly as they typically need several movable dispersive optical components (e.g., motorized gratings, interferometers) and thousands of detectors or filter arrays. Although these benchtop spectrometers offer high resolution and wide spectral range, their large physical dimensions restrict them from being widely adopted in numerous portable applications, such as consumer electronics, smart wearable devices, drone integration and remote sensors3.
Over the past few years, various approaches have been developed to realize miniaturized spectrometers with a significant reduction in their cost and footprint by replacing the bulk dispersive optical components with tunable filter arrays or compact interferometers4,5. These techniques offer excellent performance in general, but they cannot be scaled down below the sub-millimetre scale due to fundamental physical limitations in the optical path length. To overcome these restrictions, a “reconstructive-type” operation principle has recently been developed that relies on special computational algorithms for spectral reconstruction6,7. Examples of such approaches include spectrometers realized on colloidal quantum dots8, in-situ dynamically modulated perovskites9, compositionally engineered10 and superconducting11 nanowires. Two-dimensional (2D) materials12,13 and their heterostructures14,15 have been used to fabricate ultracompact computational spectrometers owing to their inherently dangling-bond-free surfaces, atomically sharp interfaces, layer-dependent bandgap, and electrically tunable photoresponse16,17,18. However, the operation bandwidth, precision, and portability of all these miniaturized spectrometers are generally restricted by the bandgap engineering limits of their chosen materials19.
In this work, we report a reconstructive broadband spectrometer based on van der Waals heterostructures consisting of an overlapping tunnel junction of two semiconducting 2D materials—molybdenum disulfide (MoS2) and black phosphorus (BP). In contrast to the previous 2D materials-based spectrometers13,14,15, which typically use both gate-source and drain-source voltages to tune wavelength-dependent photoresponses, here, we propose and demonstrate to use only the drain-source voltage to create an electrically tunable spectral response for spectral reconstruction. In this design, the spectrometers are much more compact and simpler in architecture, as gate contacts and insulation layers are not required. Further, in contrast to the previously reported results (e.g., pure BP12, graphene13, MoS2/WSe214, ReS2/Au/WSe215), we choose BP/MoS2 heterostructures because the BP/MoS2 junctions exhibit the transition of band alignment between staggered- and broken-gap. This can effectively switch the charge carrier transport from thermionic emission to band-to-band tunneling only by tuning the source-to-drain bias voltage across the junction without gating20,21,22,23,24. This drastically reduces the contact resistance under the reverse bias voltage and enables low-voltage operation without a gate terminal. Our new van der Waals tunneling-diode-driven spectrometer has a broad operation bandwidth from the visible to near-infrared (NIR) ranges. Additionally, the demonstrated small operation voltage change (~2 V) of the diode-based spectrometer design offers immense potential in realizing practical devices for various on-chip applications.
Results
Operation principle
Figure 1 illustrates the operation principle of our diode-based broadband spectrometer concept. It involves three distinct steps: (a) learning, (b) testing, and (c) reconstruction. The optoelectronic properties of a diode can be tuned in a controlled manner by applying a tunable external electric bias potential across the junction. As shown in Fig. 1a, the responses of the diode are first studied with multiple known monochromatic optical inputs individually. This leads to a distinct photoresponse matrix of the device. The corresponding photoresponsivity can be treated as a function of both the incident light wavelength (λ) and the external electric bias potential (Vds) applied across the junction. The entire photoresponse information is encoded into a single responsivity matrix (R, Right panel of Fig. 1a) whose electrically tunable spectral response elements (Rij) are denoted as-
where Iph, λ, and P represent the generated photocurrent, the wavelength of the incident light, and the optical power of the incident light, respectively. In the testing step, as shown in Fig. 1b, the bias-dependent photocurrent response of the device corresponding to the incident light with an unknown spectrum is measured. For signal processing, the incident light is assigned to an unknown spectrum function (S(λ)). The photoresponse data measured in the testing step, together with the calibrated response functions obtained in the learning step, are then processed to reconstruct (S(λ)) by solving a system of linear equations10:
where λmin and λmax refer to the operational bandwidth of the spectrometer. We compute its constrained least-squares solution to reconstruct the unknown incident light spectrum (Fig. 1c).
Device scheme and characterization
Figure 2a illustrates the schematic view of our BP/MoS2 diode-based spectrometer fabricated on a Si substrate with a 300 nm thermally grown SiO2 capping layer. Note that hexagonal boron nitride (hBN) passivation layers encapsulate the device. There is an additional Al2O3 encapsulation on top of the hBN. The device fabrication process is described in the Methods section. A corresponding optical microscope image of the spectrometer is provided in Fig. 2b, where multilayer BP and MoS2 flake edges are depicted with dashed yellow and black lines, respectively. We fabricate electrodes on both BP and MoS2 flakes to analyze their electrical characteristics.
In this work, we use multilayer flakes to fabricate the BP/MoS2 heterostructure to achieve high photoresponse. Atomic force microscopy (AFM) mapping on the heterostructure spectrometer presented in Fig. 2b reveals the thicknesses of the BP and the MoS2 flakes as ~45 and ~33 nm, respectively (Supplementary Fig. S1). To confirm material quality, we perform Raman measurements on pure channels and overlapping regions of the devices. Figure 2c shows the Raman spectra of bare MoS2 (black line), BP (blue line), and their heterostructure regions (red line) excited by a 532 nm laser at room temperature. Two distinct Raman modes of MoS2 are observed in the range of ~330–510 cm−1: E2g1 at ~383 cm−1 and A1g at ~407 cm−1; while BP shows three phonon modes: Ag1 at ~362 cm−1, B2g at ~439 cm−1, and Ag2 at ~467 cm−1, in good agreement with previous reports22,25. Raman peaks of the heterostructure region comprise the contribution from both flakes, indicating the formation of a high-quality van der Waals heterojunction.
We perform electrical measurements on the tunnel diode to reveal its intrinsic properties. For the heterojunction, drain bias is applied to BP, while MoS2 is connected to the source terminal. In this measurement configuration, electrons are injected from the source electrode to the MoS2 flake and subsequently transported to the BP flake through the heterostructure region. Eventually, the electrons are collected by the drain electrode. Figure 2d presents the output characteristics of our BP/MoS2 heterostructure on a logarithmic scale. The junction offers comparable conduction for forward and reverse Vds. The superior current level under reverse bias is attributed to the band-to-band tunneling (BTBT) mechanism, as discussed later. Since we use multilayer BP and MoS2 flakes, the quantum confinement effect can be ignored. Consequently, their band profiles are considered the same as their bulk counterparts. BP and MoS2 have electronic bandgaps of ~0.3 and 1.29 eV, respectively. Multilayer BP typically behaves as a degenerate p-type semiconductor whose Fermi level lies in the valence band, while multilayer MoS2 shows normal n-type behavior (Supplementary Fig. S2). When a forward Vds is applied across the heterojunction, as shown in Fig. 2e, the band of BP shifts downward compared to its equilibrium state. Consequently, the interface barrier height for electrons decreases. Therefore, conduction band electrons (majority carriers) of MoS2 effectively surmount the reduced interface barrier height, enabling forward conduction. This forward conduction is a thermionic emission process where the forward current increases exponentially with increasing Vds in the ideal case. Since BP is a strong p-type and MoS2 is an n-type semiconducting material, their respective minority carrier concentration is intrinsically low, limiting their contribution to forward conduction. Figure 2f shows a heterostructure band diagram under reverse bias. The degenerated BP offers high doping concentration, and its electrons filled below the valence band level can tunnel to the allowed states above the conduction band level of MoS2.
Spectrometer demonstration
Upon optical irradiation of the heterojunction, the generation of photocurrent occurs depending on the signatures of excitonic states in the absorption spectrum of constituent flakes26,27. When the BP/MoS2 diode is excited with light in the visible wavelength region, as shown in Fig. 3a, the electrons in the valence bands of both MoS2 and BP can be excited to their respective conduction bands. Under forward bias (left panel of Fig. 3a), the photoexcited electrons in the conduction band of MoS2 are injected into the conduction band of BP. Under reverse bias (right panel of Fig. 3a), the valance band electrons of BP tunnel to the conduction band of MoS2 while the photoexcited electrons in the BP conduction band drift to the MoS2 conduction band and result in a strong photocurrent signal.
In the learning process of the spectrometer, we first measure the output curves of the BP/MoS2 heterojunction diode under multiple known incident lights with a spectral width of ~10 nm. For the operation demonstration at the visible spectral region, we vary the incident excitation from ~500 nm to 800 nm in a step of 10 nm. Figure 3b shows the calculated photoresponsivity (R), also called responsivity in short, as a function of the wavelength of incident lights and the bias voltage applied across the heterojunction. The responsivity is defined as R = Iph/P; where Iph and P represent the photocurrent and the optical power of incident light, respectively. After encoding the spectral response matrix for the learning process, we measure unknown incident light spectra following the spectrum reconstruction process (Supplementary S3). In brief, we first measure the bias-tunable photocurrent of the unknown incident light (Fig. 1b). Afterwards, we compute its constrained least-squares solution to reconstruct the spectrum using an adaptive Tikhonov method10,14. Details of the optical setup, electrical, and optoelectrical measurements are provided in the Methods section. As shown in Fig. 3c, the quasi-monochromatic spectra reconstructed with our spectrometer agree with the reference spectra measured using a commercial spectrometer. The average peak-wavelength difference (∆λ) between reconstructed and reference spectra is calculated as ~2.5 ± 0.9 nm (Fig. 3c). The small second peak at ~675 nm is a computational error. In principle, such artifacts can be suppressed by filtering or improving the base model. We also carry out broadband measurement (Supplementary Fig. S4), which agrees well with that of the commercial spectrometer.
We now demonstrate the operation of our spectrometer at the NIR spectral region. Under NIR illumination at the heterojunction tunnel diode, as shown in Fig. 4a, the photocurrent generation process is mainly attributed to the direct-bandgap transition in BP since the incident photons cannot provide sufficient energy to excite the electrons in MoS2 from its valence band-to the conduction band. Under reverse bias (right panel of Fig. 4a), the photoexcited electrons in the BP drift to the MoS2 conduction band. To demonstrate operation capability at the NIR region with high spectral resolution using our single-junction ultraminiaturized spectrometer, we construct a spectral response matrix by choosing a small (fine) learning step. Figure 4b presents the responsivity matrix obtained in the learning process for monochromatic incident lights ranging from ~1550 to 1560 nm in a step of ~0.5 nm. After learning, we test our spectrometer. The results shown in Fig. 4c indicate our broadband spectrometer is highly efficient in resolving NIR signals. It can successfully distinguish two wavelengths at ~1557 nm and ~1558 nm. With larger (coarse) learning steps, the peak-to-peak-wavelength accuracy would be compromised, mainly due to a lower peak signal-to-noise ratio11,14, as shown in Supplementary Fig. S5. We also conduct spectrometer stability and reproducibility measurements (Supplementary Fig. S6), which confirm operational stability over a ~10-day period and good device-to-device variation (~1.2 nm in the visible range and ~0.02 nm in the NIR range).
Figure 5 compares our results with state-of-the-art miniaturized spectrometers. Our single-junction tunnel diode-based spectrometer offers comparably high peak-wavelength accuracy with a broad operational window spanning the visible and NIR regions. Note that the operation bandwidth of our device is expected to cover ~4 μm, as the bandgap of multilayer BP is ~0.3 eV27. However, currently, we cannot demonstrate the operation in the mid-infrared range due to the unavailability of tunable light sources in the mid-infrared range for the learning and reconstruction process. In contrast to the previously reported triode-based spectrometers12,14,15, where high gate voltage (typically >15 V) is required for operation, our tunnel diode-based spectrometer needs a lower voltage for tuning, which in principle reduces power consumption. Our diode-based spectrometer concept has the following main advantages: (1) simple and compact device structure without the gate terminal; (2) low driving voltage (<2 V) for low power consumption; and 3) broadband operation from the visible to mid-IR for a much wider range of applications.
Discussion
In conclusion, we have successfully demonstrated a reconstruction-type tunneling-diode-based broadband spectrometer. The spectrometer is electrically reconfigurable, and it does not require any filter or, photodetector array, or other bulky dispersive components to achieve high resolution with nanometer accuracy. The low operation voltage and compact footprint of the spectrometers offer immense possibility of integration with numerous portable applications such as consumer photonics and affordable on-chip spectral imaging (e.g., smart agriculture, remote sensing, and environmental monitoring).
Note added in proof: During proofreading, we became aware of recent work28 showcasing a similar MoS2/BP heterojunction based spectrometer operating in the ~1700 to 3600 nm range, validating our device’s predicted mid-infrared functionality in Table 1.
Methods
Device fabrication and characterization
We used Si substrates with a 285 nm thick SiO2 capping layer for device fabrication. hBN-encapsulated high-quality van der Waals heterostructures were prepared with commercially available hBN, BP, and 2H-phase MoS2 crystals (2D Semiconductors, HQ Graphene) following the deterministic dry-transfer method. First, BP/MoS2/bottom-hBN heterostructures were realized following a layer-by-layer flake stacking process that was performed with a motorized 2D transfer stage (Graphene Industries) placed inside an Argon gas-filled glovebox (MBRAUN) to maintain oxygen and water level below 0.1 ppm. Then, the chips were spin-coated with poly(methyl methacrylate) resist for patterning with electron beam lithography (EBL Raith EBPG5200). Afterwards, to realize 5/100 nm thick Ti/Au metal contacts on the EBL patterned structures, the chips were loaded to a vacuum electron beam evaporator (Angstrom) followed by acetone lift-off. Then, top hBN flakes were transferred onto the heterostructures inside a glovebox to protect them from atmospheric degradation. For process optimization, devices were annealed at 180 °C in a high vacuum (<0.05 mPa) for 2 h (Vacuum Furnace Webb). For additional protection against ambient conditions, an Al2O3 layer of thickness 20 nm was deposited at 120 °C employing an atomic layer deposition process (Beneq TFS-500). Finally, the Ti/Au electrodes were connected to a printed circuit board (PCB) by wire bonding (Wire Bonder Bondtec 5330). The topology of the fabricated hBN encapsulated BP/MoS2 heterostructures was analyzed with an atomic force microscope (AFM Dimension Icon, Bruker).
Raman measurements
All Raman spectra were acquired at room temperature using a micro-Raman spectrometer (WITec alpha300R) in a confocal backscattering geometry. A frequency-doubled Nd:YAG solid-state laser at 532 nm was used for excitation. The incident beam was focused perpendicularly onto the samples with a spot size of ~1 μm using an objective lens (100X, 0.9 NA). The backscattered signals were collected through the same objective lens and subsequently dispersed with an 1800-groove/mm grating and detected by a Si-charge-coupled camera. All experiments are performed at low excitation power (P ≤ 0.2 mW) to avoid thermal damage to the samples.
Electrical and optoelectrical measurements
Wire-bonded device chips were mounted to our home-built setup consisting of source meters (Keithley 2400 and 2401), and a custom-designed optical system allowed us to focus the laser beam on the desired locations of the spectrometer devices. Source and drain electrodes were connected to MoS2 and BP, respectively. The drain to source voltage was always swept from −2 V to +2 V (which is well below the breakdown voltage of BP29–30). We used a supercontinuum laser source (SuperK Extreme, NKT Photonics) for photo-measurements in the visible range. The spectral bandwidth of the source was controlled by a tunable spectral filter (SuperK Varia, NKT Photonics) that allowed us to tune the spectral bandwidth to ~10 nm. For photo-measurements at the NIR region, we used a distributed-feedback laser source (Photonetics Osics 3610RA00). All measurements were done at room temperature, and data acquisition was performed with a customized LabVIEW program. For spectral references, the visible and the NIR spectra were measured by commercial spectrometers (FLAM-S and Anritsu MS9740A from OceanOptics).
Data availability
All data needed to evaluate the findings of this study are available within the Article, its Supplementary Information and Source Data files and are also available from the corresponding author upon request. Source data are provided with this paper.
Code availability
Code used for the spectral reconstruction is publicly available at Github (https://github.com/fonig/Reconstruction)14.
References
Bannon, D. Cubes and slices. Nat. Photon 3, 627–629 (2009).
Zhou, J. et al. Single-particle spectroscopy for functional nanomaterials. Nature 579, 41–50 (2020).
Savage, N. Spectrometers. Nat. Photon 3, 601–602 (2009).
Bacon, C. P. et al. Miniature spectroscopic instrumentation: applications to biology and chemistry. Rev. Sci. Instrum. 75, 1–16 (2003).
Wolffenbuttel, R. F. et al. State-of-the-art in integrated optical microspectrometers. IEEE Trans. Instrum. Meas. 53, 197–202 (2004).
Candes, E. J. & Tao, T. Near-optimal signal recovery from random projections: universal encoding strategies? IEEE Trans. Inf. Theory 52, 5406–5425 (2006).
Yang, Z. et al. Miniaturization of optical spectrometers. Science 371, eabe0722 (2021).
Bao, J. & Bawendi, M. A colloidal quantum dot spectrometer. Nature 523, 67–70 (2015).
Guo, L. et al. A single-dot perovskite spectrometer. Adv. Mater. 34, 2200221 (2022).
Yang, Z. et al. Single-nanowire spectrometers. Science 365, 1017–1020 (2019).
Kong, L. et al. Single-detector spectrometer using a superconducting nanowire. Nano Lett. 21, 9625–9632 (2021).
Yuan, S. et al. A wavelength-scale black phosphorus spectrometer. Nat. Photon 15, 601–607 (2021).
Ma, C. et al. Intelligent infrared sensing enabled by tunable moiré quantum geometry. Nature 604, 266–272 (2022).
Yoon, H. H. et al. Miniaturized spectrometers with a tunable van der Waals junction. Science 378, 296–299 (2022).
Deng, W. et al. Electrically tunable two-dimensional heterojunctions for miniaturized near-infrared spectrometers. Nat. Commun. 13, 4627 (2022).
Geim, A. K. & Grigorieva, I. V. Van der Waals heterostructures. Nature 499, 419–425 (2013).
Xia, F. et al. Ultrafast graphene photodetector. Nat. Nanotechnol. 4, 839–843 (2009).
Koppens, F. et al. Photodetectors based on graphene, other two-dimensional materials and hybrid systems. Nat. Nanotechnol. 9, 780–793 (2014).
Chaves, A. et al. Bandgap engineering of two-dimensional semiconductor materials. NPJ 2D Mater. Appl. 4, 29 (2020).
Deng, Y. et al. Black phosphorus–monolayer MoS2 van der Waals heterojunction p–n diode. ACS Nano 8, 8292–8299 (2014).
Tang, K. et al. Electronic properties of van der Waals heterostructure of black phosphorus and MoS2. J. Phys. Chem. C 122, 7027–7032 (2018).
Ye, L. et al. Near-infrared photodetector based on MoS2/black phosphorus heterojunction. ACS Photonics 3, 692–699 (2016).
Liu, X. et al. Modulation of quantum tunneling via a vertical two-dimensional black phosphorus and molybdenum disulfide p–n junction. ACS Nano 11, 9143–9150 (2017).
Hong, T. et al. Anisotropic photocurrent response at black phosphorus–MoS2 p–n heterojunctions. Nanoscale 7, 18537–18541 (2015).
Wu, F. et al. Gate-tunable negative differential resistance behaviors in a hBN-encapsulated BP-MoS2 heterojunction. ACS Appl. Mater. Interfaces 13, 26161–26169 (2021).
Radisavljevic, B. et al. Single-layer MoS2 transistors. Nat. Nanotechnol. 6, 147–150 (2011).
Higashitarumizu, N. et al. Anomalous thickness dependence of photoluminescence quantum yield in black phosphorous. Nat. Nanotechnol. 18, 507–513 (2023).
Wang, H. et al. Room-temperature self-powered infrared spectrometer based on a single black phosphorus heterojunction diode. Nano Lett. 24, 326–330 (2024).
Ahmed, F. et al. High electric field carrier transport and power dissipation in multilayer black phosphorus field effect transistor with dielectric engineering. Adv. Funct. Mater. 27, 1604025 (2017).
Ahmed, F. et al. Impact ionization by hot carriers in a black phosphorus field effect transistor. Nat. Commun. 9, 3414 (2018).
Meng, J. et al. Detector-only spectrometer based on structurally colored silicon nanowires and a reconstruction algorithm. Nano Lett. 20, 320–328 (2020).
Acknowledgements
The authors acknowledge the funding from the Academy of Finland (314810, 333982, 336144, 352780, 352930, and 353364), the Academy of Finland Flagship Program (320167, PREIN), the EU H2020-MSCA-RISE-872049 (IPN-Bio), Business Finland (AGATE), the Jane and Aatos Erkko foundation, the Technology Industries of Finland centennial foundation (Future Makers 2022), and ERC (834742,101082183). This research was conducted at the Micronova, Nanofabrication Centre of Aalto University.
Author information
Authors and Affiliations
Contributions
Z.S. conceived of the idea and supervised the research. M.G.U. designed the experiment, fabricated spectrometer devices, and performed measurements on all the devices. S.D., A.M.S., F.A., X.C., and H.H.Y. assisted M.G.U. in optical and electrical characterization. S.D., L.W., N.F., and W.C. developed the reconstruction code. M.G.U., S.D., L.W., W.C., and Z.S. analyzed the data. A.C.L., Z.Y., H.L., H.H.Y., and T.H. commented on the experimental results and helped with the data analysis. M.G.U. wrote the manuscript. All authors participated in the scientific discussion and contributed to the writing of the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Peer review
Peer review information
Nature Communications thanks Doron Naveh, Haoxuan Sun and the other anonymous reviewers for their contribution to the peer review of this work. A peer review file is available.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Source data
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
Uddin, M.G., Das, S., Shafi, A.M. et al. Broadband miniaturized spectrometers with a van der Waals tunnel diode. Nat Commun 15, 571 (2024). https://doi.org/10.1038/s41467-024-44702-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-024-44702-8
- Springer Nature Limited