Introduction

Terahertz (THz) wave lies in the frequency gap between microwave and the infrared, and the corresponding wavelength ranges from 3 mm to 30 μm. Because of its great potential in communication, biomedicine, security, and so on1,2,3, THz technology has attracted more and more attention in recent decades. The key problem affecting the practical application of THz technology is the lack of functional devices with excellent performance. This is mainly due to the absence of materials in nature that can directly interact with THz waves. Fortunately, an artificial composite material consisting of the periodically arranged structural units called the metamaterial (MM) has emerged to solve this problem. Unlike natural materials, MMs can achieve some abnormal electromagnetic (EM) properties by adjusting the resonant unit structure, such as negative refractive index4, perfect lensing5, invisibility6, perfect absorption7, and EM induced transparency (EIT)8. Because of their unique EM properties, MMs have also been used in THz functional devices, such as modulators9, filters10, and optical switches11.

MM absorbers (MMAs) have great application value in stealth, detection, communication and other fields, and have gradually become one of the research hotspots in THz fields. In 2008, Landy et al. first proposed an MMA with perfect absorption characteristics7. Subsequently, various MMAs working in different frequency bands were realized in turn, including microwaves12,13, THz waves14,15, visible and infrared bands16,17. In THz band, Tao et al. designed and manufactured the first narrowband absorber18. Thereafter, dual-band19, triple-band20, and multi-band THz absorbers21 were reported in succession. However, due to the strong dispersion of resonant structures of the early MMA, the broadband THz absorbers were greatly limited. The multi-resonator cascade and dispersion control22,23,24 have also been proposed to extend the absorption bandwidth of MMAs. In these absorbers, the performances have been fixed according to the designed structures, which still limits their practical applications. Thus, it is urgently needed that the active regulation and control of MMAs can be realized by means of heat, electricity, and light.

Recently, researchers have employed some functional materials to achieve tunable THz MMAs. For example, Padilla first demonstrated the electrically tunable THz absorbers based on hybrid liquid crystal MM structures in 201325. In 2017, by combining a planar metal disk resonator with liquid crystal, Wang at al. realized a triple-band tunable THz MMA with sub-wavelength thickness26. In the same year, by utilizing the hybrid metasurface structure composed of graphene and gold, Zhao et al. achieved excellent THz absorption spectra (0.53–1.05 THz) with wide incident angles for both TE and TM waves27. Meanwhile, graphene-assisted highly tunable liquid crystal THz MMA was also demonstrated28. However, the tunable range of the constitutive parameters of the graphene and liquid crystal materials is limited, which leads to the low modulation depth of absorbers.

The THz response of vanadium dioxide (VO2) is essentially different from these of graphene and liquid crystal. As a photoelectric functional material with high quality, VO2 is a kind of metal oxide with a unique insulator to metal transition (IMT) characteristic, which can be realized by the external excitation of light, heat, or stress29. The conductivity of VO2 film can be changed by 4–5 orders of magnitude and the phase transition can be completed in the order of sub picosecond30. Recently, the active tunable MMA based on IMT properties of VO2 has been implemented in other EM frequencies. For example, in the microwave band, Wen et al. realized an active tunable MMA based on thermally control by combining VO2 with conventional MM resonance and the achieved modulation depth was 63.3%31. In the near infrared band, Zhu et al. experimentally realized an effective MMA capable of spectral control by minimizing the thermal mass of VO2 materials. The device had a tuning range of 360 nm and a modulation depth of 33% at the resonant wavelength32. In the infrared band, Kocer et al. proposed a thermally tunable MMA with mixed gold-VO2 nanostructure arrays33. In the optical frequency band, Huang et al. designed the Au/VO2/Au MM structures and the superior performance of dynamic temperature-controlled optical switch was theoretically and experimentally demonstrated34. However, in THz band, the tunable MMA based on IMT characteristics of VO2 is still undeveloped.

In this paper, we propose a thermally tunable broadband THz MMA with mixed VO2. The designed metadevice is a simple sandwich structure, including symmetrical L-shaped VO2 metasurface layer and VO2 film ground plane, and these two layers are separated by a thin polyimide (PI) dielectric spacer. The simulation results show that the metadevice is almost transparent to THz wave at low temperature (50 °C) because of the insulation phase of VO2 and the maximum absorption is about 11%. With the increasing temperature, VO2 gradually transforms from insulation to metal phase, the whole structure is equivalent to a metallic MM structure. When the temperature is over 70 °C, the frequency bandwidth corresponding to absorption above 80% is as wide as 2.0 THz, and the absorption is even close to the perfect absorption of 100% at a specific frequency (1.96 THz). The maximum tunable range of the metadevice can be realized from 5% to 100% by an external thermal excitation. The broadband strong absorption behavior of the proposed metadevice is mainly due to the resonant response of the L-shaped structure and this physical mechanism is analyzed in detail by changing the geometry size of the metasurface structure, intermediate dielectrics, and the VO2 ground plane. By simulating the surface electric field distribution of metasurface structure, we prove that the excellent tunability of the absorber is attributed to the IMT characteristics of VO2. Meanwhile, we find that the cooling process is less sensitive to the decreasing temperature due to the different conductivity characteristics of VO2 materials and the absorber is insensitive to the incident angle variations up to 50°, which is beneficial to practical application over a wide range of incident angle.

Results

Hybrid VO2 metamaterial absorber

Generally, the typical MMA is a three-layer coupling structure consisting of the metal film mirror, dielectric, and metasurface resonance layers. By designing and optimizing the size, structure, and arrangement of the artificial elements of the MMA, the effective permeability (μeff) is selected to be equal to the effective dielectric constant (εeff), and the surface impedance z(w) of the absorber in a specific frequency band can be adjusted to match the free space, which guarantees that the incident EM waves are hardly reflected. The continuous metal film ground plane is always used to prevent EM waves from penetrating the absorber, so that the transmission is almost zero. Thus, the EM waves can be basically confined to the interior of the MMA until they are completely depleted.

Reference to the physical mechanism of the absorber, the THz MMA based on hybrid VO2 sandwich structure is proposed and the structural schematic diagram is shown in Fig. 1. The resonant layer in Fig. 1a is composed of a symmetrical L-shaped VO2 array with a thickness of t1 = 2 μm. The lower surface of the MM structure is a layer of VO2 thin film with a thickness of t2 = 4 μm, which is much thicker than the rough 1 μm skin depth of VO2 in metal phase around 1.0 THz, which effectively suppresses the transmitted energy of THz waves. The resonant and reflective layers are separated by PI polymer materials with a thickness of d = 20 μm. The front view of a unit cell is shown in Fig. 1b and the L-shaped VO2 films are symmetrical with respect to the diagonal. Both the lengths of the horizontal and vertical arms of the L-shaped metasurface structure are l = 30 μm, the widths are w = 2 μm, and the period is px = py = 50 μm. Because of the unique IMT characteristic of VO2, we predict that the designed structure is characterized as a fully permeable THz film at low temperatures due to the insulation phase of VO2. While VO2 changes from insulation to metal phase at high temperatures, the resonant and reflective layers composed of VO2 materials start to work and the whole structure is characterized as a THz absorber. Therefore, based on thermal excitation, we can effectively control the THz absorption characteristics in real time with the assistance of VO2 MMs.

Figure 1
figure 1

Hybrid VO2 metamaterial and broadband tunable THz absorber. (a) Schematic diagram of the proposed hybrid VO2 MMA, including a middle layer of the PI dielectric spacer (the cyan region) with the thickness d = 20 μm, a top layer of the symmetrical L-shaped VO2 metasurface structure with the thickness t1 = 2 μm, and a bottom layer of the VO2 ground plate (the purple region) with the thickness t2 = 4 μm. (b) Front view of a unit cell, the geometric parameters are l = 30 μm, w = 2 μm, Px = Py = 50 μm. (cf) Simulated THz spectrum of the proposed hybrid VO2 MMA at different temperatures for TE mode. (c) Transmission. (d) Reflection. (e,f) Absorption for the heating and cooling processes. (g) Absorption spectrum of the proposed broadband absorber at the high temperature (70 °C) for different incident angles of THz waves.

With the gradual maturity of material preparation processes and micromachining technology, it is possible to manufacture MM structures in the THz band. So far, based on micro-nano manufacturing technology, THz MM structures with structural unit sizes smaller than tens of nanometers can be successfully manufactured. Therefore, we predict that the designed micron-scale THz MM structure can be easily realized. The continuous VO2 film in the structure can be prepared by the sol-gel method, which requires less cost and can be molded at one time. In addition, other preparation methods such as vacuum evaporation, sputtering, and pulse laser deposition (PLD) are sometimes employed. The quality and uniformity of the prepared VO2 film can be accurately characterized by using high-resolution X-ray diffraction (XRD), Raman spectroscopy, and Fourier-transform infrared spectroscopy (FTIR). And then by utilizing photolithography and ion beam etching methods, the double L-shaped metasurface resonance structure composed of VO2 material can be easily obtained. Here, it is worth noting that compared to most active THz MM devices mixed with multiple materials, the proposed MM sandwich structure can be easily processed, mainly because the structure contains only VO2 phase change material and no other functional materials, which effectively simplifies the complexity of the MM structure.

The simulated THz transmission and reflection of the proposed hybrid VO2 MMA at different temperatures for heating process are shown in Fig. 1c,d, respectively, and the absorption is shown in Fig. 1e. All the blue and red solid lines represent THz spectra at low (50 °C) and high (70 °C) temperatures, respectively. It can be clearly seen that the THz transmission is above 69% in the whole frequency range at 50 °C, the corresponding reflection is less than 26%, and the absorption is less than 11%. Interestingly, as the temperature increases, the transmission and reflection decrease gradually, which leads to an increase in the absorption. When the temperature increases to 70 °C, the transmission is almost attenuated to zero and the overall reflection is also greatly suppressed, thus an extremely high absorption (greater than 80%) in a continuous range of frequencies with a bandwidth of about 2.0 THz can be obtained, especially at 1.96 THz, a nearly perfect absorption of 100% is achieved. The maximum tunable range of the absorption can be modulated from 5% to 100%. Consequently, we have successfully demonstrated a broadband tunable THz absorber based on thermally control near the room temperature, and the modulation depth is up to 95%, which is difficult to be achieved in the other THz absorbers.

In addition, the THz absorption spectra of the cooling process are also simulated and shown in Fig. 1f. As the temperature decreases gradually, we find that the THz absorption is not attenuated significantly, that is to say, the cooling process is less sensitive to the decreasing temperature. We preliminary predict that the main reason for this fascinating phenomenon is the hysteresis effects of VO2 IMT characteristics29. When the temperature is 50 °C, VO2 is in the insulation phase and fully transparent to the incident THz waves, which results in the high transmission, low reflection and absorption. However, the increasing temperature makes the VO2 materials gradually change from the insulation to the metal phase, so the VO2 film ground plane gradually suppresses the transmission energy of THz waves, the symmetrical L-shaped metasurface resonant structures attached to the upper surface of the metadevice work on and the incident THz electric fields are gradually coupled into the metal phase VO2, which efficiently reduces the reflection. When the temperature increases to 70 °C, VO2 is completely transformed into its metal phase and the conductivity is just one order of magnitude lower than that of gold35, the incident THz waves can hardly penetrate the metadevice and the transmission is zero. At this time, the resonant response of the L-shaped metasurface structures reaches its maximum, so that the reflection is also significantly weakened, which leads to the strong absorption of the proposed MMA. On the other hand, the conductivity of VO2 film is not completely reversible and the similar hysteresis loops during the heating and cooling processes29 will lead to the different resonant responses, which is responsible for the device sensitivity to the temperature.

A two-dimensional plot of the absorption spectrum of the oblique THz incident angle on the proposed absorber is depicted in Fig. 1g. The calculated steps of the incident angle and frequency are set to be 1° and 0.001 THz, respectively. It is notable that with the increasing incident angle, the absorption can be maintained at a high level and the absorption bandwidth is also stable for most angles (the red region). The proposed THz absorber is extremely insensitive to the incident angle variations up to 50°, which would be beneficial to practical applications. When the incident angle is beyond 50°, the absorption is obviously attenuated and the absorption bandwidth is narrowed. This is because the strong resonant response of the L-shaped metasurface structure cannot be excited by large oblique incident angle.

Broadband and perfect absorption

Although we have just simulated THz absorption spectra at several temperatures in Fig. 1, we can still roughly deduce the tunable behavior of the proposed metadevice by observing the overall trend of the curve variations. To better demonstrate the superior and continuous tuning characteristics of the thermal controlled absorber, a two-dimensional plot of the temperature-dependent THz absorption spectrum in the frequency range of interest is shown in Fig. 2a,b. The calculated steps of the frequency and temperature are 0.001 THz and 1 °C, respectively. Figure 2a illustrates the THz absorption spectra for the heating process from 50 °C to 70 °C. With the gradual increase of temperature, we can clearly see that the absorption does not change significantly (the blue region) until 57 °C, but there is still no obvious resonant absorption in the whole spectrum (the green region) until 60 °C, the strong THz absorption band is excited and the bandwidth is gradually broadened with the increasing temperature (the red region). When the temperature gets 68 °C, the absorption bandwidth is increased to about 2.0 THz and reaches saturation.

Figure 2
figure 2

Continuous tuning performance and corresponding physical mechanism. The temperature-dependent THz absorption spectra of the proposed hybrid VO2 MMA are depicted in the heating process (a) and the cooling process (b). (cj) Surface electric field distribution corresponding to the perfect absorption at 1.69 THz of the proposed L-shaped metasurface structure for the heating process at different temperatures (50–70 °C).

Meanwhile, to clearly describe the tunable characteristic of the absorber during cooling process, a temperature-dependent two-dimensional graph is also depicted in Fig. 2b, which is quite different from that of the heating process. We find that with the decrease of temperature, the absorption does not change obviously (the red region) until 64 °C. With the further decreasing temperature, the absorption and its bandwidth gradually become small and narrow, respectively. When the temperature drops to 56 °C, the resonant absorption disappears as shown by the green region. The simulated results more clearly demonstrate that the modulations of THz absorption are different in the heating and cooling processes and the sensitive temperature in the cooling process is lower. The temperature-dependent two-dimensional plots unambiguously indicate a drastic but continuous spectrum tuning behavior before saturation for the heating and cooling processes. Based on the detailed analysis above, with the assistance of the IMT characteristic of VO2 materials, the superior performance of the proposed broadband tunable THz absorber has been well demonstrated and the achieved condition of thermal excitation is close to room temperature, which greatly promotes the practical application of the designed metadevice.

It is well demonstrated that the proposed broadband absorber can achieve active tunability of wide range with the assistance of the VO2 phase change material. To further study the physical mechanism of the achieved tunable behavior based on temperature control, the surface electric field distribution for heating process at different temperatures is simulated and the results are shown in Fig. 2c–j. It can be found that there is almost no electric field distribution on the surface of L-shaped structure at 50 °C, indicating that the incident THz waves almost completely penetrate the MM structure. This is because VO2 exhibits insulation characteristics and is transparent to THz waves at low temperature. The ground plane and L-shaped layer composed of VO2 have no effect on THz waves and result in the low absorption. With the increase of temperature from 58 °C to 68 °C, the electric field is coupled to the two ends of the VO2 arms and gradually diffused to the surface of the whole arm and the cross area because VO2 is gradually transformed from the insulation to metal phase. The L-shaped resonant response and the reflection of VO2 ground plane are enhanced simultaneously, which results in a sharp increase in the absorption. In addition, we find that the surface electric field distributions at 68 °C and 70 °C are almost the same. Because VO2 is completely transformed into its metal phase at 68 °C, the resonant response induced by the VO2 metasurface structure will not be further enhanced with the increasing temperature. Therefore, based on external heating excitation, the proposed hybrid VO2 MM structure can realize the alternation between the fully transparent thin film and the broadband absorber in THz band.

Here, besides the dramatic manipulation of the response, it is important to emphasize that since the IMT phase transition time of the VO2 material can be completed in sub-picoseconds, our proposed broadband tunable THz absorber based on hybrid VO2 MMs can achieve ultra-fast dynamic response under external thermal excitation. The capable of offering ultrafast modulation of THz radiation is difficult to achieve in other THz modulators. The proposed hybrid metamaterial concepts may open up new avenues for highly tunable ultrafast THz devices.

Absorption mechanism and performance

To investigate the physical mechanism of the broadband absorption characteristic of the proposed absorber at high temperature, it is necessary to clarify the contribution to THz absorption of each layer in the designed sandwich structure. Here, the VO2 ground plane in metal phase is used as a mirror to enhance absorption. As shown in Fig. 3a, it can be clearly seen that the achieved maximum absorption without VO2 film substrate in the whole spectrum is only 33%, much smaller than that with VO2 plane, which fully confirms the role of VO2 mirror. In addition, the effect of dielectric loss (PI) in the middle layer on THz absorption is also studied and the simulation results of THz absorption spectra for different dielectrics (loss and loss free) are depicted in Fig. 3b. We find that there is no obvious change in absorption and bandwidth. So, the dielectrics have the limited effect on the absorption. Unlike the other absorbers14,36, the insensitivity of dielectric layers in the proposed one might be significantly applicable in many fields.

Figure 3
figure 3

Effects of MM structure on broadband absorption performance. (ae) Absorption spectra of the proposed hybrid VO2 MMA at high temperature (70 °C) with and without VO2 gound plane (a), with different dielectric layers (loss and loss free) (b), with different L-shaped metasurface structures (c), with different arm lengths from 20 μm to 30 μm (d), and with different arm widths from 2 μm to 9 μm (e). (fh) Surface electric field distribution corresponding to the resonance absorption frequencies of 1.44 THz and 3.42 THz with w = 9 μm, and of 1.96 THz with w = 2 μm, respectively.

The single vertical and inverted L-shaped resonance structures are also designed to study the physical mechanism of the broadband absorption. The simulated results are shown in Fig. 3c. It can be seen that the two absorption spectra almost coincide due to the symmetry of the structure. However, the spectrum bandwidth with the absorption above 80% is only about 1.0 THz, which is much narrower than that of double L-shaped (2.0 THz). And the strongest absorption is still less than 90%. So, the double L-shaped structures can enhance the resonant response and lead to the strong enough absorption.

Through the detailed analysis above, it can be firmly believed that the energy of incident THz waves is mainly dissipated by the symmetrical L-shaped VO2 metasurface resonance layer. To further demonstrate the strong absorption induced by the L-shaped structure, we simulated the THz absorption spectra with different geometric parameters. Firstly, the dependence of the absorption spectra on the width w is simulated and shown in Fig. 3d. It is surprising to find that with the increasing width from 2 μm to 9 μm, the broadband absorption spectrum is destroyed and gradually splits into two strong resonant peaks near 1.44 THz and 3.42 THz, illustrating that width has a great impact on the resonances between the L-shaped structure and the THz radiation. However, from other points of view, the THz absorber with dual resonance absorption channel also has important development prospects in practical applications.

As another important geometry parameter of the L-shaped structure, the influence of arm’s length on absorption is also studied. The absorption spectra of the arm length changing from 20 μm to 30 μm are shown in Fig. 3e. With the increasing arm length, the absorption spectrum is broadened gradually and the absorption is also enhanced. This is because the L-shaped resonant characteristic is mainly due to the electric field coupled to the surface of the arms. In addition, we find that the increased arm length leads to a red shift in the absorption spectra. It can be explained that the different resonant modes have been produced by changing the size of the structure. The arm length is inversely proportional to the resonant frequency37. With the increasing arm length, the resonance absorption band will accordingly shift to the low frequency range. Consequently, it can be concluded that the geometrical size and the numbers of L-shaped structures will have a great impact on the THz absorption. The optimal size of the double L-shaped structure can provide the high-performance THz absorber.

To better understand the physical mechanism of the absorption spectrum varying with the width of L-shape, the surface electric field distribution is simulated and shown in Fig. 3f–h. The electric field distributions corresponding to the resonance frequencies of 1.44 THz and 3.42 THz are illustrated in Fig. 3f,g, respectively, when the width is w = 9 μm. It can be clearly observed that the two arms of the L-shaped structure are very close to each other, resulting in the strong dipole resonance (1.44 THz) at both ends of the arm. The obvious difference can be found that the electric field corresponding to the resonant mode at high frequency (3.42 THz) is not only distributed at both ends of the arms, but also at the edges of the arms. As the width decreases, the two ends of the arms are gradually separated, which weakens the dipole resonance, so the dual resonance absorption mode is suppressed gradually. When the width is reduced to 2 μm, the two L-shaped structures are completely separated. By observing the electric field distribution at the perfect absorption frequency of 1.96 THz shown in Fig. 3h, we find that the electric field is fully coupled to the whole surface of the two L-shape structures, which leads to the broadband and high THz absorption spectrum.

To clearly show the different resonance characteristics of the L-shaped metasurface structures in the whole absorption spectrum, we simulated the surface electric field distribution corresponding to different absorption frequencies and the results are presented in Fig. 4. We find that the absorption at 0.5 THz is only 5%, as shown in Fig. 4a. There is almost no electric field distribution on the surface of the structure, indicating that the resonant response does not occur. The MMA does not interact with the incident THz waves, which leads to the extremely low absorption. When the frequency gradually shifts to 0.9 THz, the absorption is increased to 22%. This is because a weak resonant response is generated in the L-shaped structure and the electric field is coupled at both ends of the arms as shown in Fig. 4b. And the absorption is also increased. We have simulated the surface electric field distribution corresponding to the strong resonance absorption frequencies of 1.3 THz, 2.0 THz, and 2.7 THz with the absorption above 80%, and the results are shown in Fig. 4c–e, respectively. Obviously, the electric field is strongly coupled to the whole surface of the L-shaped structure, including two ends of the arms, arm edges, and the cross areas. In these cases, the resonant responses are very strong and the absorptions are also intense. Notably, when the frequency shifts to 3.7 THz, away from the frequency band with high absorptions, the coupled electric field intensity of the L-shaped surface is greatly reduced in Fig. 4f, indicating that the resonant response disappears and the absorption is also decreased. Therefore, by simulating the surface electric field distributions at different frequencies, we have clearly demonstrated that the L-shaped resonant structure is entirely responsible for the broadband and strong absorption behavior of the proposed MMA.

Figure 4
figure 4

Physical mechanism of broadband absorption. (af) Surface electric field distributions of the L-shaped VO2 metasurface structure in the proposed broadband absorber at different frequencies of 0.5 THz, 0.9 THz, 1.3 THz, 2.0 THz, 2.7 THz, and 3.7 THz. The dashed line denotes the absorption bandwidth of about 2 THz.

So far, researchers have proposed various approaches to modulate THz waves in broadband. For example, hybrid two-dimensional materials such as graphene THz broadband absorbers have been widely proposed38,39,40,41,42. However, due to the limited tunability of the conductivity of graphene itself, which greatly limits the modulation depth and tunable range of the device. Moreover, the conductivity of graphene can be effectively modulated by the applied bias voltage, so most of the reported THz devices contain electrode structures, which greatly increases the difficulty of processing. At the same time, the electronically controlled modulation method cannot achieve non-contact tunability, which limits the practical application of the device to some extent. The proposal of photo-excited broadband tunable THz absorber effectively solves this problem43,44,45, but because of the limited spot size of the external pump light and the uncontrollable transmit power, this device cannot effectively regulate large area THz radiation. Recently, in the THz band, a novel tunable broadband device based on coded metasurface has been reported46,47,48,49. Through the real-time programmable design of the metasurface structure, the amplitude, phase and polarization of THz wave can be effectively regulated, but the complex structure increases the processing difficulty of the device. In addition, it is well known that, compared with other types of modulators, the mechanically tunable THz devices were first proposed50,51, its advantages lie in enabling strong tunable capacity, avoiding dynamic decay in resonance strength, and maintaining Q factors during tuning. However, the THz devices that utilize mechanical stimulation for dynamic tuning, have received much less attention, mainly because of the more complicated fabrication process and the relatively slow response time of mechanical systems.

Different from all methods in the past, our proposed broadband tunable THz absorber based on hybrid VO2 MMs can achieve a higher modulation depth at room temperature. Considering the hysteresis behavior of VO2 materials and the IMT phase transition time on the order of picoseconds, the proposed THz device exhibits a strong memory effect and has an ultra-fast response time. At the same time, unlike most active THz MMs devices, the structure we designed contains only one VO2 material in addition to the dielectric, so it is easy to process.

Discussion

Based on the IMT characteristic of VO2, we have proposed a broadband tunable THz MMA. At low temperature (50 °C), the designed MM structure has lower absorption of incident THz waves due to the insulation phase VO2. However, with the increasing temperature from 50 °C to 70 °C, the VO2 film gradually transforms from the insulation to metal phase, at this time, the proposed structure gradually transforms into a broadband THz absorber. An extremely high absorption (greater than 80%) in a continuous range of frequencies with a bandwidth of about 2.0 THz has been obtained. Especially at 1.96 THz, a nearly perfect absorption has been achieved. The maximum tunable range of the absorption has been realized from 5% to 100% by external thermal excitation. Benefiting from the phase-change VO2 material, the applied external thermal excitation is close to room temperature, which plays an important role in promoting the practical application of the metadevice. The large dynamic range and convenient thermal control are impossible to be achieved in other absorbers. Meanwhile, we have also demonstrated that the proposed THz absorber is extremely insensitive to the incident angle variations up to 50°. We believe that the concept of the proposed THz device could be readily extended to other frequency regimes. Such a thermally tunable broadband THz absorber may be applied in various fields, such as imaging, cloaking, modulating, and filtering.

Methods

The full-wave EM simulations are implemented with the finite element solution by using the commercial software package of COMSOL Multiphysics. The open boundary is applied along the z-direction, which is upward and normal to the metasurface. To simulate the infinite periodic array structure, the periodic boundary conditions along the x-y plane (x and y directions) are performed. The incident THz wave is selected as a TE mode and perpendicular to x-y plane. To ensure the accuracy of the calculation results, the ultra-fine grids are adopted and the frequency step is set to be 0.001 THz. The dielectric constant of the PI is 2.88–0.09i. The IMT characteristic of VO2 in THz band needs to be described by the Bruggeman effective medium theory (EMT). The dielectric function εC can be expressed as52

$${\varepsilon }_{C}=\frac{1}{4}\{{\varepsilon }_{D}(2-3{f}_{v})+{\varepsilon }_{M}(3{f}_{v}-1)+\sqrt{{[{\varepsilon }_{D}(2-3{f}_{v})+{\varepsilon }_{M}(3{f}_{v}-1)]}^{2}+8{\varepsilon }_{D}{\varepsilon }_{M}}\},$$
(1)

where fv is the volume fraction of the metal component, εD and εM are dielectric functions of VO2 thin films in insulation and metal phase, respectively29. In addition, the functional relationship between the fraction fv and the temperature T can be described by the Boltzmann function,

$${f}_{v}={f}_{{\rm{\max }}}(1-\frac{1}{1+\exp [(T-{T}_{0})/{\rm{\Delta }}T]}),$$
(2)

where T0 is the phase transition temperature, ΔT is the transition width, and fmax is the maximum volume fraction. By combining Eqs (1) with (2), the conductivity of VO2 thin films corresponding to different temperatures in the phase transition process is expressed as35

$$\sigma =-\,i{\varepsilon }_{0}\omega ({\varepsilon }_{C}-1).$$
(3)

The reflection and transmission of the proposed MMA can be acquired by simulating the complex frequency-dependent S parameters (S11 and S21), so the absorption coefficient A can be calculated by53

$$A=1-{R}_{s}-{T}_{s}=1-{|{S}_{11}|}^{2}-{|{S}_{21}|}^{2},$$
(4)

where Rs = |S11|2 and Ts = |S21|2 are the reflection and transmission coefficients, respectively.