1. IntroductionPhotodetectors (PDs), which operate by converting incident light into electrical signals, are the mainstay of a variety of industrial and scientific applications, such as imaging systems, optical communications, environmental surveillance, and biological sensing.[1–5] The semiconductor, as an active layer, is the essential part of the PD, and can absorb the incident photons and generate electron and hole pairs. Besides, a built-in or applied electric field is necessary to separate the electron and hole pairs, which are collected by electrons to produce an electric current. Up to now, a variety of semiconductors has been applied for conventional PDs, including Si, Ge, group II–VI (PbS and PbSe), group IIB–VI (Hg1−xCdxTe), and group III–V (GaN and InxGa1−xAsyP1−y). These PDs have been fully investigated and there has been impressive progress on the improvement of photodetection and device configuration design. However, there are several drawbacks, such as the complex manufacturing, high cost, and mechanical inflexibility, which limit broad applications of conventional PDs.
Low-temperature solution-processed semiconductors, such as organic semiconductors, nanomaterials, and quantum dots, are an emerging class of photoactive materials because they are compatible with the simple, low-cost, large area, and flexible manufacturing process.[5] Among them, metal halide perovskites have attracted wide research interests due to their direct bandgaps, long carrier diffusion lengths, high absorption coefficients, and high defect tolerance.[6–10] These outstanding features make metal halide perovskites widely applied in solar cells.[11–14] As a result, the power conversion efficiency of perovskite solar cells has risen from 3.8% to 23.3% in the past few years.[15,16] Based on these significant improvements, the perovskite film formation, chemical composition, and hole/electron transport materials have been amply developed.[17,18] In addition, metal halide perovskites also have great potential in many other optoelectronics, such as light-emitting diodes (LEDs), lasers, and PDs.[19–25] Particularly, there already have been plenty of research studies about perovskite PDs in material compositions and morphologies, as well as device architectures and engineering. Various strategies have been developed to synthesize perovskites in different morphologies (polycrystalline films, single crystals, and low-dimensional nanostructures) for PDs. Meanwhile, device-engineering strategies are applied to improve the performance of the perovskite PDs. Therefore, it is necessary to give a comprehensive review of the perovskite PDs in material compositions and device engineering.
In this review, we first introduce the performance parameters that influence the performance of perovskite PDs, the configurations of which can be divided into three types: photodiodes, photoconductors, and phototransistors. Next, we mainly discuss PDs based on perovskites in different morphologies, including polycrystalline films, single crystals, nanowires/nanorods, quantum dots/nanocrystals, and two-dimensional (2D)/quasi-2D perovskites. Then, several strategies to fabricate high-performance or special-purpose perovskite PDs are illustrated and analyzed. Finally, we provide a brief conclusion and outlook about both the achievement and challenges of perovskite PDs.
2. PD basics2.1. PD performance parametersThere are several parameters used to evaluate the performance of perovskite PDs, including responsivity R, detectivity D
*, linear dynamic range (LDR), and response time (rise/decay time). A brief overview of these parameters is presented as follows.
2.1.1. Responsivity (R)The responsivity is defined as the ratio of photocurrent to incident-light intensity, which measures the electrical output per optical input. It is given by
where
Jph is the photocurrent, and
Llight is the incident light intensity. The responsivity of a PD is usually expressed in units of amperes per watt of incident radiant power. As defined above,
R is proportional to the external quantum efficiency (EQE), which evaluates the conversion rate from photons to electrons/holes of PDs. In consequence, responsivity can also be expressed as
where
h is the Planck constant,
c refers to the speed of light in a vacuum,
λ is the light wavelength, and
e refers to the absolute value of electron charge.
Another parameter closely related to responsivity is photoconductive gain G, which is defined as the average number of circuit electrons generated per photocarrier pair.[26] The device responsivity can be calculated from photoconductive gain
where
η (
) is the quantum efficiency, which indicates the probability that a single photon incident on the device will generate a photocarrier pair that contributes to the detector current. So far, the gain
G can also be calculated by the measured carrier-recombination lifetime and transit time, which is widely used to estimate the optical gain in photoconductors with the photoconductive effect
[27]:
where
τ is the excess minority carrier lifetime, and
τT is the carrier transit time.
τT can be expressed as
L/
μ E, where
L is the channel length,
μ is the carrier mobility, and
E is the electric field intensity provided by bias voltage.
2.1.2. Detectivity (D
*)The specific detectivity D
* characterizes the weakest level light that can be detected by PDs, which is determined by the responsivity and noise of PDs. The D* is given by
where
A is the effective area of PDs, Δ
f is the electrical bandwidth, and
inoise is the noise current. When the dark current is dominated by the shot noise,
D* can be expressed as
Another parameter characterizes the noise level of the detector, and the detectorʼs ability to detect weak light signals is known as the noise equivalent power (NEP), which is defined as the signal incident light power on the PD when the signal-to-noise ratio S/N=1 is detected (the signal-to-noise ratio is the ratio of the effective value of the signal to the effective value of the noise). Since the noise level is proportional to the root of the measurement bandwidth Δ f, the NEP specifies measurement results at a 1 Hz bandwidth. Consequently, the NEP is equal to the reciprocal of D
*:
2.1.3. LDROne important characteristic for PDs is the capacity to perform an identical responsivity over a wide range of light intensity, which is known as the LDR:
where
is the photocurrent measured at a light intensity of
, and
Jd is the dark current. The LDR is important because the intensity of the light signal cannot be accurately detected and calculated beyond this range.
2.1.4. Response time (rise/decay time)PDs are not only evaluated by sensitivity, but also by speed. The response time is characterized by rise time τr and fall time τf of its response to the optical signal. Generally, the rise time and fall time are the times taken for the photocurrent to rise to 63.2% and drop to 36.8% of the steady-state values, respectively.[25,28] However, when PDs are modulated in a pulsed case, the rise time is defined as the time to transit between 10% to 90% of the peak output value, and vice versa for the fall time.[29–32]
2.2. PD configurationsGenerally, there are three main types of configurations for perovskite PDs: photodiodes, photoconductors, and phototransistors.[25,33–37] According to the spatial layout of the photoactive medium and electrodes, perovskite PDs can be divided into two major categories: the lateral type, and the vertical type (Fig. 1(a)).
A photodiode is a p–n junction that has a depleted semiconductor region with a high electric field that serves to separate photogenerated electron–hole pairs. Photodiodes derived from a p–n photodiode include, but are not limited to, the following: p–i–n photodiodes (Fig. 1(b)), heterostructure photodiodes, and Schottky barrier photodiodes.[26] As for perovskite photodiodes, most of them have a p–i–n structure and are very similar in configuration to perovskite solar cells. When the photodiode is under light, photocarriers are separated by the built-in electric field, and the Voc is open-circuit voltage. The difference is that the perovskite photodiode works under a reverse applied field in order to provide a low dark current and a fast response time. Due to the built-in fields at the interface, this type of detector can work at a very low driving voltage or even at 0 V bias.[28,31,38–42] There are hole/electron transporting layers applied to enhance the performance of both devices. Besides, an extra blocking layer to improve the performance ulteriorly has also been introduced.[33,34,38] As shown in Table 1, the perovskite photodiode usually exhibits a low dark current, but it also has a lower photocurrent. As a result, this type of device usually exhibits a high detectivity D
* and a large LDR. In contrast with the photoconductor, the responsivity Rλ and EQE of the photodiode are lower because of the low gain of the photodiode.
Table 1.
Table 1.
| Table 1.
The advantages and disadvantages of different device configurations.
. |
A photoconductor is based on the photoconductive effect, in which an electric field applied to the material by an external voltage source causes the electrons and holes to be transported.[26] In comparison to the photodiode, the perovskite photoconductor has a simple configuration and an easy process (Fig. 1(c)); thus, the latter is more convenient to integrate.[43,44] Besides, this type of detector has a larger dark current than photodiodes, which leads to a small detectivity and a narrower LDR (Table 1). The photocurrent amplification in the photoconductor due to the recycling of photoexcited electrons (holes) makes it possible to acquire a high responsivity Rλ and EQE. However, the large gain and EQE of the photoconductor come at the cost of response time because both the gain time and response time are determined by the life time of trapped carriers.[27] Hence, a trade-off between the gain and response times is required in order to achieve optimal device performance. As mentioned above, the perovskite photodiode configurations are vertical and usually include conventional and inverted types (Figs. 2(a) and 2(b)), while perovskite photoconductors can be both lateral and vertical devices (Figs. 2(c) and 2(d)). Lateral structure devices usually employ a perovskite film, and the electrode spacing (
) is larger than that of photodiodes (
). Due to the simple configuration, lateral structure devices more easily achieve flexibility. For the vertical structure photoconductor, due to the smaller electrode spacing, a high gain can be achieved with a low driving voltage. The active layers of most vertical structure perovskite PDs are made by perovskite single crystals, that is, the dark current is lower due to less defects, and the detectivity is subsequently higher. However, the single-crystal perovskite layer is typically very thick in order to acquire a high responsivity Rλ, which makes the process more difficult than in other types.[36]
As mentioned above, the lateral structure photoconductor is relatively facile to fabricate. However, it usually has a large dark current and a relatively slow response, and thus the phototransistor is designed with a gate electrode to modulate the charge transport. Phototransistors usually have a three-terminal configuration, which is similar to field-effect transistors. The gate electrode is isolated from the perovskite layer by a thin dielectric film, and thus the charge transport can be modulated by applying a gate voltage (Fig. 2(e)). Compared with the lateral structure photoconductor, the gain of the phototransistor is larger due to the modulation by the gate bias; hence, the responsivity and EQE are further improved. Wu and co-workers reported a pure perovskite phototransistor based on solution-processed perovskite films, and provided direct evidence for their superior carrier transport property with ambipolar characteristics.[25] As a result, the phototransistor acquired a large responsivity and an ultrafast response speed, which demonstrated that the phototransistor configuration is advantageous for enhancing the gain and responsivity without sacrificing the response speed. The fly in the ointment is that the driving voltage of the phototransistor is usually larger than that of other configurations. To further improve the performance of transistors, one feasible approach is hybridization with other materials (Fig. 2(f)), such as 2D layered materials,[45] quantum dots,[46] and plasmonic nanoparticles.[37]
3. Perovskite materialsGenerally, halide perovskites have the formula ABX3, in which A and B are cations, and X represents halogen anion (Cl−, Br−, and I−) (Fig. 3(a)). In consideration of the formability[49–51] and photoelectric conversion properties,[52–54] the cations suitable for metal halide perovskites are limited. Small organic molecules (such as
(MA) and
(FA)) and inorganic cations (such as Cs+ and Ru+) are employed as monovalent A cations. Bivalent transition metal ions (such as Pb2+, Sn2+, Ge2+, and Mn2+) are employed as B cations.
The thermal and structural instability of organic cation lead perovskite is an urgent problem that needs to be solved. Three-dimensional (3D) MA-based perovskites suffer from intrinsic instability due to the relatively volatile MA cations that are released from the film during heating, and this process is accelerated in the presence of moisture. In addition, MAPbI3 was found to be prone to degradation following exposure to moisture, heat, oxygen, and light.[55–58] It was previously reported that FA-based perovskites exhibited much greater thermal stability than MA-based perovskites.[59] Nevertheless, the black perovskite phase of pure FAPbI3 is thermodynamically stable only above 160 °C.[60] Although all-inorganic perovskite (CsPbI3) has better thermal stability, the most stable phase at room temperature is not a black phase with high photoelectric conversion efficiency. Notably, recent studies have revealed that mixed perovskites showed improved stability and device performance. The MA/FA mixture demonstrates that a small amount of MA induces a preferable crystallization of FA perovskite into its photoactive black phase, resulting in a more thermally and structurally stable composition than pure MA or FA compounds.[60,61] Furthermore, by substituting FA with Cs cations, FAPbI3 can be stabilized in the desired black α-phase to form a thermally and structurally stable perovskite.[62,63] Besides, the band gap and the optical absorption band border can be modulated by the substitution of A cations since the band gap changes from 1.48 eV for FAPbI3 to 1.73 eV for CsPbI3.[64] Although the band gap can also be modulated by the ratio of halogens, the range of the adjustment is limited considering the structural stability of perovskite. By substituting FA with Cs cations, the region of structural instability in the Br–I phase space could be pushed to higher energies, and thus potentially achieve a structurally stable mixed-halide perovskite with a band gap of 1.75 eV.[59] For B cations, the bivalent lead ion is usually the best choice to attain high photoelectric conversion efficiency despite the lead being toxic. Sn, Ge, Bi, Cu, and many other elements have been used for replacing Pb in order to avoid the toxicity to the human body and environment.[65–70]
Different from the 3D perovskites mentioned above, layered perovskites have a general formula of (RNH3)2[ABX3]nBX4, where R denotes a long chain alkyl or aromatic group (such as aliphatic or aromatic alkyl ammonium), and n is relevant to the number of repeated structural units that contain the A cation[71] (Fig. 3(b)). The perovskite structure changes when n changes from 0 to
: n = 0, a pure 2D structure with formula of (RNH3)2BX4; n=defined integer, a quasi-2D structure; and
, a 3D ABX3 structure. Up to now, 2D and quasi-2D perovskite have attracted much attention due to their robustness to moisture and high luminescence efficiency.[72–74]
As mentioned in Section 1, outstanding physical and chemical properties make perovskite materials the ideal building blocks for constructing different types of optoelectronic devices. Several morphologies of materials are available for different devices. Polycrystalline film is usually the wise choice for a high-efficiency perovskite solar cell, due to the large optical absorption coefficient over a broad wavelength range, ultrafast charge generation, high and microsecond-long balanced mobility, and slow recombination of perovskite materials. For LEDs, nanocrystal, quantum dots, or even 2D perovskite gain much higher luminous efficiency. However, single crystals and nanowires are more suitable for lasers because they require a higher crystal quality. Similarly, perovskites applied in PDs have various morphologies. The representative examples of PDs processed by different types of perovskite materials are presented in Table 2.
Table 2.
Table 2.
Table 2.
Materials and key parameters of perovskite PDs.
.
Device structure/material |
Morphology |
Sensing light |
Responsivity @ Vbias
|
Detectivity D
* @ Vbias
|
LDR |
Response speed |
Ref. |
|
|
wavelength |
(light source, intensity) |
(light source, intensity) |
|
(rise time/fall time) |
|
Photoconductor/MAPbI3
|
polycrystalline films |
310–780 nm |
@ 3 V (365 nm,
) |
— |
— |
|
[47] |
Photodiode/MAPbI3−xClx
|
polycrystalline films |
300–800 nm |
— |
8 ×1013 Jones @ −0.1 V |
dB |
180 ns/160 ns |
[38] |
|
|
|
|
(550 nm,
) |
|
|
|
Phototransistor/MAPbI3
|
polycrystalline films |
400–800 nm |
@ VDS=−30 V, VGS=−40 V |
— |
— |
|
[25] |
|
|
|
(white light,
) |
|
|
|
|
Photoconductor/MAPbI3
|
polycrystalline films |
300–800 nm |
@ −1 V (740 nm) |
— |
85 dB |
|
[31] |
Photoconductor/MAPbI3−xClx
|
polycrystalline films |
254 nm |
@ 2 V(white light,
) |
— |
— |
|
[85] |
Photodiode/MAPbI3
|
polycrystalline films |
300–800 nm |
— |
∼3×1012 Jones @ 0 V (700 nm) |
∼170 dB |
|
[24] |
Photodiode/MAPbCl3
|
single crystals |
365 nm |
@ −15 V (365 nm,
) |
1.2 ×1010 Jones |
— |
24 ms/62 ms |
[48] |
Photoconductor/MAPbBr3
|
single crystals |
380–600 nm |
@ 5 V (525 nm) |
Jones |
— |
|
[30] |
Photoconductor/MAPbI3
|
single crystals |
275–790 nm |
@ 1 V (532 nm,
) |
— |
76 dB |
|
[98] |
Photodiode/FAPbI3
|
single crystals |
380 nm |
@ −0.1 V (380 nm,
) |
— |
— |
12.4 ms/17.2 ms |
[94] |
Photodiode/CsPbBr3
|
single crystals |
410–570 nm |
@ −10 V (550 nm) |
— |
— |
— |
[95] |
Photoconductor/MAPb(BrxI1−x)3
|
single crystals |
405–710 nm |
@ 2 V (460 nm) |
1.15 ×1012 Jones |
— |
3.4 ms/3.6 ms |
[108] |
Photodiode/MAPbBr3
|
single crystals |
∼555–585 nm |
— |
2 ×1010 Jones @ 4 V (570 nm) |
— |
∼1.6 ms |
[36] |
Photoconductor/MAPbI3
|
nanowires |
400–750 nm |
@ 1 V (530 nm,
) |
2 ×1013 Jones |
— |
|
[120] |
Photoconductor/MAPbI3
|
nanowires |
633 nm |
@ 1 V (633 nm,
) |
— |
— |
0.35 ms/0.25 ms |
[114] |
Photoconductor/MAPbI3
|
nanowires |
532 nm simulated 1 sun |
— |
— |
— |
0.12 s/0.21 s |
[221] |
Photoconductor/Csx(MA)1−xPbI3
|
nanowires |
530 nm |
@ 5 V (530 nm,
) |
2.5 ×1011 Jones |
— |
— |
[113] |
Photoconductor/MAPbI3
|
nanowires |
370–780 nm |
@ 5 V (550 nm,
) |
1.73×1011 Jones |
|
|
[123] |
Photoconductor/CsPb(Br/I)3
|
nanowires |
532 nm |
— |
— |
— |
0.68 s/0.66 s |
[112] |
Photoconductor/CsPbI3
|
nanocrystals |
470–750 nm |
— |
— |
150 dB |
24 ms/29 ms |
[140] |
Photoconductor/CsPbI3
|
nanocrystals |
470–750 nm |
— |
— |
150 dB |
24 ms/29 ms |
[140] |
Photoconductor/CsPbBr3 + Au nanoparticles |
nanocrystals |
300–550 nm |
@ 2 V (520 nm) |
4.56 ×108 Jones |
— |
0.2 ms/1.2 ms |
[137] |
Photoconductor/MAPbI3−xClx
|
nanocrystals |
300–800 nm |
|
2.8 ×1016 Jones |
92 dB |
/0.445 ms |
[222] |
Phototransistor/CsPbBr3−xIx–graphene |
nanocrystals |
400–700 nm |
@ (405 nm,
) |
∼1016 Jones |
— |
0.81 s/3.65 s |
[138] |
|
|
|
|
@ (405 nm,
) |
|
|
|
Photoconductor/MAPbI3
|
2D/quasi-2D |
405 nm |
@ 1 V (405 nm) |
— |
— |
20 ms/40 ms |
[145] |
|
|
532 nm |
@ 1 V (532 nm), |
|
|
|
|
Photoconductor/(C4H9NH3)2PbBr4–graphene |
2D/quasi-2D |
470 nm |
@ 0.5 V (470 nm,
) |
— |
— |
— |
[166] |
Photoconductor/CsPbBr3
|
2D/quasi-2D |
300–550 nm |
@ 10 V (517 nm) |
— |
— |
|
[143] |
Photoconductor/CsPbBr3
|
2D/quasi-2D |
450 nm |
— |
— |
— |
17.8 ms/14.7 ms |
[144] |
Photoconductor/MAPbI3
|
2D/quasi-2D |
simulated 1 sun |
@ 2 V (white light,
) |
— |
— |
— |
[141] |
| Table 2.
Materials and key parameters of perovskite PDs.
. |
3.1. Polycrystalline filmsPolycrystalline film is one of the most common types of perovskite materials. There are many universal strategies to form polycrystalline perovskite films, such as thermal annealing, solvent annealing, atmospheric control, solvent engineering, chemical vapor deposition, vacuum flash-assisted solution processing, and the use of additives.[76–84] These strategies have been applied successfully in fabricating not only high-efficiency perovskite solar cells, but also perovskite film PDs. The preparation processes of perovskite polycrystalline films are simple and compatible with different configurations of perovskite PDs, including photoconductors, photodiodes, and phototransistors. Xie and co-workers proposed the first organic–inorganic hybrid perovskite photoconductor, the configuration of which is shown in Fig. 2(c).[47] The active layer was processed by spin-coating the precursor solution on a flexible polyethylene terephthalate (PET) substrate patterned with indium tin oxide (ITO) electrodes. To improve the quality of perovskite films on flexible substrates, Pan and co-workers developed a novel vapor–solution method to achieve uniform and pinhole-free organic–inorganic halide perovskite films on flexible ITO/PET substrates.[84] The preparation process is presented in Fig. 4(a). The PbI2 layer was first deposited on the patterned ITO/PET substrate, followed by the spin-coating of the MAI layer; then, the substrate with films was annealed at 100 °C for 10 min. The device is shown in Fig. 4(b). These flexible PDs showed an excellent photoresponse with an R value of
at a low working voltage of 1 V (Fig. 4(c)), and exhibited remarkable flexural stability and durability under various bending situations with their optoelectronic performance well retained (Fig. 4(d)). Besides flexible devices, the polycrystalline perovskite films were also deposited on other substrates, such as Si/SiO2 and ITO/glass to prepare simple but high-photoresponse photoconductors.[19,39,85–87]
As for photodiodes, Yang and co-workers presented a solution-processed high-performance PD based on organic–inorganic hybrid CH3NH3PbI3−xClx film using an “inverted” device configuration,[38] the energy diagram of which is shown in Fig. 4(e); the photogenerated carriers are separated by the built-in electric field. The ITO side collects electrons, and the Al side collects holes. By adding a hole-blocking layer that used conjugated polymers (2,9-dimethyl-4,7-diphenyl-1,10-phenanthroline (BCP) or poly[(9,9-bis(
-(N,N-dimethylamino)propyl)-2,7-fluorene)-alt-2,7-(9,9-dioctylfluorene)] (PFN)), the dark current of the device was greatly reduced (Fig. 4(f)). In addition, the photocurrent remained relatively unchanged at a low voltage range. Thus, the detectivity of the photodiode approached 1014 Jones (
) at −100 mV, which was one order of magnitude higher than that of the Si PD in the same spectral region. Compared with the photoconductor, the photodiode based on polycrystalline perovskite films showed a faster transient response. Devices with an active area of 0.01 cm2 showed a rise time of 180 ns and a decay time of 160 ns (Fig. 4(g)). Due to the complex configuration of photodiodes, the performance of devices depends not only on the perovskite layer, but also on the electron/hole transport layer as well as the overall energy level matching of the device. Consequently, improving the device performance by increasing the quality of the perovskite layer is limited.[88,89] There have been several studies about perovskite photodiodes with the similar “inverted” device configuration. To improve the detectivity of devices, inter-layers were added to reduce the dark current.[24,42,90]
Although the configuration of the phototransistor is different from that of the photoconductor, the polycrystalline perovskites applied are similar. Wu and co-workers fabricated a phototransistor based on polycrystalline perovskite (Fig. 2(f)), and provided direct evidence for their superior carrier transport property with ambipolar characteristics.[25] The thickness of the perovskite layer is a crucial factor determining the performance of the phototransistor, since one should make a balance between enough light absorption and an effective gate tuning effect. Thus, the optimum perovskite thickness was about 100 nm, and the corresponding phototransistor displayed typical ambipolar I–V curves at drain voltages of −30 V and 30 V (Fig. 4(h)). As we mentioned before, the photoresponse (
) and transient response speed (
) stayed at a relatively high level (Figs. 4(i) and 4(j)). Different from the general polycrystalline perovskite films, Bakr and co-workers fabricated an orientationally pure crystalline (MAPbI3) hybrid perovskite film by a thermal-gradient-assisted directional crystallization method that relied on the sharp liquid-to-solid transition of MAPbI3 from an ionic liquid solution.[91] Phototransistors based on these perovskite films with low trap-state density and controlled crystal orientation showed a conspicuous photoresponse. Moreover, the demonstration of this unique polycrystalline-based perovskite phototransistor provided an essential guideline for material optimization through crystallization processing and for future developments of novel optoelectronic devices.
3.2. Single crystalsCompared with polycrystalline perovskites, single-crystal perovskites possess many unique properties: high purity, few grain boundaries, and enhanced thermal and moisture stabilities. There are several reported methods for synthesizing perovskite single crystals: inverse temperature crystallization (ITC),[48,92–95] antisolvent vapor-assisted crystallization,[96] top-seed solution growth,[97] bottom-seeded solution growth,[98] and solvent acidolysis crystallization.[99] Among of them, ITC is the simplest and most commonly used approach. It is suitable to use the ITC method when the perovskite exhibits inverse temperature solubility behavior in certain solvents. MAPbX3 perovskites exhibit fascinating inverse solubility trends in solvents like γ-butyrolactone (GBL), N,N-dimethylformamide (DMF), dimethylsulphoxide (DMSO), or their mixtures.[92] As shown in Fig. 5(a), the precursor solutions were heated from room temperature and kept at an elevated temperature to initiate crystallization. For MAPbBr3, by setting the temperature of the heating bath at 80 °C, usually
crystals were formed in the case of a 1 M solution of PbBr2 and MABr in DMF. Unlike MAPbBr3, ITC of MAPbI3 was only possible in GBL solution (no precipitates were observed in DMF or DMSO), with the bath temperature set to 110 °C. It is also worth noting that neither of the precursors PbX2 and MAX showed any reverse dissolution behavior (i.e. the saturated solution of a single precursor did not show precipitation upon heating), thus suggesting that this phenomenon was related to the perovskite structure. In particular, the growth rate (maximum at
) of the crystal was an order of magnitude greater than the previously reported highest growth rate.[100] Besides, the high-quality single crystalline properties of large grain size, few grain boundaries, high charge carrier mobility, low trap density, long charge carrier diffusion lengths, fast-component excitons lifetimes, and slow-component lifetimes, were confirmed by various characterization techniques such as single-crystal x-ray diffraction analysis, steady-state absorption and photoluminescence, and carrier lifetime measurements. With these outstanding characteristics, perovskite single crystals have been applied in PDs with unique functions, including narrowband PDs,[36,101] integrated PDs,[43,102] visible-blind ultraviolet (UV)-PDs,[48,103] self-powered PDs,[104,105] and high-energy ray photon detection PDs.[106,107] Huang and co-workers fabricated hybrid perovskite single-crystal vertical photoconductors that have a very narrow spectral response.[36] The thickness of the perovskite layer was about 1 mm, much thicker than the polycrystalline perovskite layer applied in PDs (Fig. 5(b)). There was a surface-charge recombination-enabled narrowband photodetection mechanism. The charge carriers are generated mostly in a narrow region near the Au electrode since the light penetration depth is very small (
) due to the large absorption coefficient of the hybrid perovskite materials. Thus, the charges generated by the above-bandgap photoexcitation can be quenched easily because of the severe surface-charge recombination. Furthermore, the EQE of PDs was greatly influenced by the bias voltage (Fig. 5(c)) and the thickness of the perovskite layer (Fig. 5(d)). Above all, the device showed an ultra-narrow EQE peak with a full width at half maximum (FWHM) of
, a high sensitivity with a detection limit down to
, and a high off-resonance rejection ratio of
. Thinking outside the simple single crystalline perovskite photoconductors,[98,108] Liu and co-workers designed and constructed a large-area (
) imaging assembly composed of a 729 pixel sensor array (Fig. 5(e)).[102] The detectivity and EQE of the PD are presented in Fig. 5(f), in which the detectivity is as high as 6 ×1013 Jones, much better than commercial sensors made of silicon and InGaAs. It is contemplated that the combination of commercial chip fabrication that offers much higher resolution and the superior perovskite single crystal with high optoelectronic quality can lead to a wide range of applications such as high-speed and high-detectivity sensors, electronic eyes, etc.
3.3. Nanowires/nanorodsThere have been extensive researches about one-dimensional (1D) nanowire materials, such as carbon nanotubes, metal nanowires, metal oxide nanowires, and polymer nanowires, due to their high aspect ratio in conjunction with superior mechanical, electronic, and optical properties.[109,110] Hence, it is desirable to fabricate perovskite nanowires based optoelectronics. Generally, perovskite nanowires are prepared by the solution-phase synthesis method.[111–114] Xue and co-workers demonstrated a simple and effective method of hot-injection for synthesis of CsPb(Br/I)3 nanorods with a uniform rod-shaped structure,[112] the synthesis process of which is shown in Fig. 6(a). Cesium stock solution was obtained by dissolving the CsCO3 powder in oleic acid (OA) and octadecene (ODE) mixture. Meanwhile, the perovskite precursor solution was obtained by mixing PbBr2 and PbI2 in ODE. After heating at certain conditions, the CsPb(Br/I)3 nanorods were synthesized by injecting cesium stock solution into the precursor solution. The photoresponse of a prototypical PD based on the CsPb(Br/I)3 nanorods was studied by dropping the nanorods dissolved in toluene onto a gold interdigital electrode on a SiO2 substrate (Fig. 6(b)). The on/off ratio of the nanorod-based PD reached ∼2000, which makes it have vast application prospects in photoelectric devices. Besides, Horváth and co-workers prepared MAPbI3 nanowires through a simple slip-coating approach,[114] which opens up a new strategy toward low-temperature, solution-processed perovskite films with controlled morphology. Moreover, the MAPbI3 nanowires can be easily combined with monolayer graphene or carbon nanotubes to form heterostructures.[115,116] They also reported a MAPbI3 nanowire PD prepared by the graph epitaxial liquid–solid method, in which the nanowires were crystallized in the arrays of nanofabricated channels owing to the strong guiding effect of the nanogrooves.[117]
Based on the simple solution-phase method, there are several strategies to boost the performance of perovskite nanowires, including the self-assembly method and template-assisted method. Song and co-workers used the one-step self-assembly method to grow CH3NH3PbI3 nanowires,[118] and further applied an evaporation-induced self-assembly (EISA) method to prepare high-ordered perovskite nanowires.[119] In order to obtain a large-area aligned nanowire distribution, the substrates were tilted for a small angle of less than 15° to guide the nanowire alignment (Figs. 6(c) and 6(d)). Perovskite nanowires prepared by EISA have an average diameter of 500 nm and length of
. The PDs fabricated by the high-ordered perovskite nanowires obtained a responsivity as
, detectivity of 2.5 ×1012 Jones, and response time of ∼3 ms, which are superior to the recently reported PD performances based on organic–inorganic thin films and inorganic nanowires. Similarly, Tang and co-workers prepared single-crystalline MAPbI3 nanowires using the one-step self-assembly method,[120] and they subsequently introduced OA soaking to passivate surface defects of perovskite nanowires. Thus, the PDs based on perovskite nanowires exhibited much improved stability and outstanding sensitivity (measured detectivity of 2 ×1013 Jones). Yang and co-workers reported highly oriented and ultra-long MAPbI3 nanowire arrays fabricated by large-scale roll-to-roll micro-gravure printing and doctor blading in ambient environments.[121] It provided low-cost, large-scale techniques to fabricate large-area perovskite nanowire arrays, which showed great potential application in flexible electronic and optoelectronic devices.
Besides the commonly used self-assembly method, the template-assisted method opened up another avenue for high-performance perovskite nanowire PDs. Zhang and co-workers demonstrated a facile method for preparing porous MAPbBr3 nanowires by a self-template-directed reaction of Pb-containing nanowires with HBr and MABr at room temperature in solution.[122] Jie and co-workers reported a facile FGAVC method for large-scale fabrication of high-quality single-crystalline perovskite nanowire arrays.[123] As shown in Fig. 6(e), periodically aligned SU-8 photoresist stripes were fabricated on the SiO2/Si substrate by photolithography. The SU-8 photoresist template was subsequently dipped into perovskite precursor solutions for a few seconds and placed on a tilted glass (∼5°) in a weighing bottle together with 3 mL of CH2Cl2 solvent. The antisolvent vapor would gradually diffuse into the precursor solution, leading to the crystallization of the MAPbI3 nanowires along the sides of SU-8 photoresist strips. The PDs using the perovskite nanowires prepared by the FGAVC method demonstrated a maximum R value of
and a high gain of 104.
3.4. Quantum dots/nanocrystalsWhen the size of 3D materials is decreased to the nanometric scale, the tiny spherical particles will exhibit completely different optical and electronic properties compared with their bulk counterparts. Their size-dependent optical band gaps, size tunability, large extinction coefficient, high photoluminescence quantum yield (PLQY), and multiple exciton generation characteristics of quantum dots make them especially suitable for use in optoelectronic devices.[124–128] Perovskite quantum dots/nanocrystals also exhibit quantum-size effects similar to conventional quantum dots, and thus they can be applied in optoelectronic devices.
Generally, two methods have been widely used for the preparation of perovskite quantum dots/nanocrystals: (i) the ligand-assisted re-precipitation (LARP) method[129,130] and (ii) the hot-injection method.[99,131,132] Pérez-Prieto and co-workers first demonstrated solution-phase synthesis of perovskite colloidal quantum dots, in which the MAPbBr3 quantum dots with a size of 6 nm were prepared via re-precipitation using medium-length alkyl chain organic ammonium cations as ligands.[133] Dong and co-workers also reported a simple and versatile LARP technique for the fabrication of MAPbX3 QDs with absolute PLQYs of 50%–70%.[130] The process for the LARP technique and reaction system is illustrated in Fig. 7(a). The precursor solution was formed by dissolving PbBr2, MABr, n-octylamine, and OA into DMF. The precursor solution was subsequently dropped into toluene under vigorous stirring, and it aggregated into nanoparticles after the colloidal solution turned yellow-green. The colloidal solution in toluene was centrifuged to discard large particles, and a high-quality colloidal solution made of small-sized nanoparticle was attained.
According to the results of early research work, perovskite quantum dots/nanocrystals were most applied in LEDs.[130,131,134] However, more and more studies suggested that PDs based on perovskite quantum dots/nanocrystals also have good performance.[135–139] Early in 2013, Wang and co-workers reported a CsPbBr3 quantum dot PD, the performance of which was enhanced by employing a bilayer composite film of mesoporous TiO2 (mp-TiO2) CsPbBr3 quantum dots as photosensitizers.[135] As a result, this PD demonstrated a significantly improved on/off ratio by about three orders of magnitude. Song and co-workers synthesized MAPbBr3 plate-type nanocrystals by a novel solution reaction using octylamine as the capping ligand.[136] The synthesis of MAPbBr3−xClx and MAPbBr3−xIx nanocrystals was achieved by the halide exchange reaction of MAPbBr3 with MACl and MAI in an isopropyl alcohol solution, respectively, and the nanocrystals with different chemical compositions demonstrated full-range band gap tuning over a wide range (1.6–3 eV) (Fig. 7(b)). Moreover, PDs based on these perovskite nanocrystals showed different photoresponses depending on the halides types. For the PDs based on pure MAPbBr3 nanocrystals, the I–V curves are almost linear within the measured range (−2 V to 2 V), with a dark current of ∼1 pA and a photocurrent of
under 365 nm and 505 nm laser irradiation, respectively (Fig. 7(c)). For PDs based on mixed perovskite nanocrystals, photocurrents of those with Cl-rich composition (MAPbBr3−xClx) decreased with the increase in x, while those with I-rich composition (MAPbBrI2) exhibited the highest photoconversion efficiency (Fig. 7(d)). A strong correlation was observed between the photocurrent and photoluminescence decay time, and was rooted in the nature of the crystalline structure. Thus, the tetragonal phase exhibits higher photoconversion efficiency than that of a cubic phase. Based on the above results, the same group reported a new method, i.e. ultrasonic irradiation of precursor solutions, for synthesizing APbX3 perovskite nanocrystals, where A=MA, Cs, or FA, and X=Cl, Br, or I.[139] Band gap tuning of the nanocrystals over a wide range (1.54–3.18 eV) was achieved by controlling the composition of cations (MA, Cs, and FA) and halide anions (Cl, Br, or I). The corresponding PDs were fabricated by spin-coating the APbBr3 and APbI3 nanocrystals between Au electrodes patterned on SiOx substrates, and demonstrated a high on/off ratio over 105 at 2 V and under 365 nm illumination.
Since the long-term stability became a major concern for perovskite nanocrystalline applications, all-inorganic perovskite nanocrystals gradually showed advantages owing to their superior stability against oxygen and moisture. Lee and co-workers presented PDs based on all-inorganic CsPbX3 nanocrystals that were synthesized by a hot-injection method.[140] Besides, the CsPbCl3 and CsPbI3 were acquired by halide exchange reactions using lithium salts (LiX, X=Cl, Br, and I). PDs made of CsPbI3 nanocrystals exhibited a high on/off photocurrent ratio of 105, as well as rise and decay times of 24 ms and 29 ms, respectively. The same group also demonstrated a high-sensitivity hybrid PD based on graphene–CsPbBr3−xIx perovskite nanocrystals, which exhibits a high photo-responsivity of
and detectivity of
Jones under 405 nm and
illumination.
3.5. 2D/quasi-2D perovskitesIn recent years, 2D materials have been extensively investigated to be applied in PDs due to their excellent optical, electrical, and mechanical properties. Hence, it is desirable to reduce the dimensionality of bulk perovskite to 2D and investigate the optical–electrical characteristic of 2D perovskite-based devices. Currently, 2D perovskite materials can be divided into two types: the non-van der Waals type, and the van der Waals type. The former is derived from a 3D perovskite framework by cutting down the thickness to a single or few unit cells, such as nanoplates,[141] nanosheets,[142–145] and nanoflakes.[146] The latter is built by inserting long-chain organic cations in the “A” position to block the interaction of inorganic [BX6]4− bilayers, mainly including those quasi-2D perovskites with a formula of (RNH3)2[ABX3]nBX4 (
).[147–150]
For non-van der Waals-type 2D perovskites, there are several ways to realize the synthesis process, including the simple solution-phase method, the solution process combined with the vapor-phase conversion method, and the seed-mediated solution growth method. Bao and co-workers reported a combined solution process and vapor-phase conversion method to synthesize 2D hybrid organic–inorganic perovskite (Fig. 8(a)).[145] The PbI2 aqueous solution was first casted onto a SiO2 substrate, which was subsequently heated to a fixed temperature facilitating the nucleation of 2D PbI2 nanosheets. Then, the vaporized MAI was intercalated into the interval sites of PbI6 octahedron layers to form the 2D MAPbI3 nanosheets. The growth mechanism of the perovskite nanosheets indicated that the out-of-plane growth rate along the c-axis is much lower than that of the in-plane one because of the lower surface energy along the in-plane direction. The as-synthesized nanosheets had a relatively smooth surface with a roughness of 0.2–1.0 nm, and the height profiles depicted the single-layer MAPbI3 nanosheets with thicknesses of 1.3 nm (Fig. 8(b)). The schematic diagram of the PDs based on these materials is shown in Fig. 8(c). The PDs showed linear I–V curves under different powers of illumination, and the dark current was rather low (10−9 A) (Fig. 8(d)). Thus, the responsivity of the PDs was as high as
at 1 V bias irradiated by a weak laser (
), and the response time was 40 ms. Wang and co-workers prepared large arrays of perovskite microplates by a similar method.[151] The arrays of lead iodide microplates were grown from an aqueous solution through a seeded growth process, followed by intercalating MAI to produce perovskite crystals. In particular, the microplates can be selectively grown on pre-patterned electrode arrays to create independently addressable PD arrays and functional field effect transistors.
Song and co-workers reported high-performance flexible visible light PDs based on 2D CsPbBr3 nanosheets.[143] The high-quality and easily dispersed CsPbBr3 nanosheets (Fig. 8(e)) were prepared by using long-chain alkyl amines and OAs as the surfactants that served as growth-directing soft templates, which broke the crystalʼs inherent cubic symmetry and guided the 2D growth. In addition, the thicknesses were about 1.68 nm and 3.3 nm (Fig. 8(f)) for the as-synthesized monolayer and bilayer nanosheets, respectively, and the edge length was about
. The flexible PDs based on the CsPbBr3 nanosheet exhibited excellent electron transport properties, a high sensitivity with a light on/off ratio of
(Fig. 8(g)) under 442 nm light at a power of
, as well as high stability and outstanding flexibility (
cycles). This gives great potential to prepare ultrathin and flexible solution-based optoelectronics based on 2D perovskites.
Van der Waals-type 2D perovskites, namely, the quasi-2D perovskite, can be synthesized by non-colloidal and colloidal methods.[71] Most of the non-colloidal methods, such as the liquid-phase crystallization method[152] and direct solution-phase growth,[153], produce small crystals in solution, which are not suitable for large-area optoelectronics requiring thickness control and complete surface coverage. On the contrary, the colloidal method is easy and has a low cost associated with preparing large-area thin films. Huang and co-workers reported PDs based on 2D layer-structured perovskite with a formula of (C4H9NH3)2(CH3NH3)n−1PbnI3n+1 (n = 1, 2, and 3).[154] The perovskite film of three different 2D layer-structured perovskite materials with different layer numbers (n = 1, 2, and 3) were fabricated by spin-coating followed by thermal annealing. The structures of the layered perovskite and PDs are illustrated in Fig. 8(h). The optical band gaps of 2D perovskite with different layers were different, which could be clearly observed in the UV–vis absorption spectrum (Fig. 8(i)). Furthermore, the wavelength-dependent output currents of the layer-structured perovskite PDs were closely related to their optical band gaps. The photocurrents remained almost constant with illuminating wavelength larger than their corresponding “threshold” wavelengths, and then increased substantially when the wavelength was below the “threshold” wavelength (Fig. 8(j)). Besides, the more layers of the 2D perovskite, the higher the photocurrent of the PDs.
4. Device engineeringAlthough there are various perovskite materials for PDs, it is not enough to meet the requirements of high-performance, diverse applications, and high stability, since the different types of perovskites mentioned above have their respective shortcomings. Hence, besides the perovskite materials, device engineering of the PDs is crucial. There are highly developed strategies for perovskite PDs, such as hybridizing with other materials and interface/band gap engineering. In addition, devices with special functions, such as flexible and narrow-band perovskite PDs also enlarge the application field of perovskites.
4.1. Hybrid structure perovskite PDsIt is a common approach to improve the performance of 2D-material PDs using hybrid systems.[155,156] In addition, the hybrid structure of perovskites has been widely applied in solar cells. Therefore, it is rational to employ the hybrid structure to boost the performance of perovskite PDs. There are various materials for hybrid perovskite PDs, such as 2D materials, polymers, metal oxides, and quantum dots.
4.1.1. 2D materialsIn recent years, conventional 2D materials, which have excellent optical, electric, thermal, and mechanical properties, have been widely explored as functional layers for PDs.[155] Accordingly, many 2D materials have been studied as functional layers in PDs hybridized with perovskites. These 2D materials include, but are not limited to, graphene and its derivatives,[37,45,138,157,158] transition-metal dichalcogenides (TMDs) (such as MoS2 and WS2),[159–161] and h-BN.[162]
Cho and co-workers first fabricated a novel phototransistor consisting of graphene/MAPbI3 hybrid layers.[45] The schematic diagram of the phototransistor is illustrated in Fig. 2(f). The heavily n-doped Si wafer and thermally grown 300 nm thick SiO2 layer served as the gate electrode and dielectric, respectively, on which the n-octadecyltrimethoxysilane layer was used for reducing surface charge trap sites. As a result, the responsivity and EQE of the PDs were
and 5 ×104%, respectively. The high performances of the hybrid PD were attributed to the efficient charge transfer from the graphene to the perovskite. On this basis, Sun and co-workers reported a one-step, solvent-induced, fast crystallization deposition method to produce isolated perovskite islands on a graphene sheet for transistor channel materials. The phototransistor showed an extremely high responsivity of
and a photoconductive gain of
electrons per photon. Besides, graphene derivatives, such as reduced graphene oxide (rGO) and graphene quantum dots (GQD), were also reported to enhance the perovskite PDs.[157,163] Liu and co-workers reported controlled synthesis of a 2D-material/perovskite van der Waals solid, which paved the way for subsequent applications of hybridizing graphene derivatives with perovskite.[164] Shi and co-workers reported a high-performance nitrogen-doped GQD (NGQDs)–perovskite/mildly rGO hybrid phototransistor, in which NGQDs and rGO offered an effective and fast path for electron transfer.[163] The same group also fabricated a high-performance lead-free 2D perovskite flexible PD (with a responsivity of
and a detectivity of 1.92 ×1011 Jones under 470 nm illumination) employing rGO–P60 as transparent flexible electrodes.[165] In addition, the perovskites in the hybrid structure PDs are not limited to films, but also include nanocrystals,[138] nanowires,[115] and 2D perovskites.[166]
For TMDs, Wu and co-workers fabricated high-performance PDs based on perovskite MAPbI3/WS2 hybrid layers for the first time.[159] The schematic device structure of the PDs is shown in Fig. 9(a). The WS2 monolayer was grown on sapphire substrates using chemical vapor deposition methods, and the perovskite layer was deposited by a thermal evaporation method. Due to the superior properties of both perovskite and WS2, the hybrid structure PDs exhibited high responsivity (
) and high detectivity (2 ×1012 Jones). The on/off ratio of the hybrid device was enhanced by approximately two orders of magnitude (Fig. 9(b)) compared with the reference perovskite single-layer device. The response speed was also promoted by four orders of magnitude, owing to the high mobility of the WS2 monolayer and the efficient interfacial charge separation. Above all, 2D materials in the hybrid structure perovskite PDs enhance the charge transfer, thus improving the performance of the PDs.
4.1.2. Organic materialsOrganic semiconductors have been widely used in perovskite photodiodes as the hole/electron transport layer. Generally, the charge transport layers in perovskite photodiodes are used to modify the energy levels and reduce the dark currents.[24,90,168] Burn and co-workers demonstrated a low noise, IR-blind visible perovskite photodiode with performance metrics equivalent to commercially available silicon photodiodes.[24] The [6,6]-phenyl-C61-butyric acid methyl ester (PC60BM)/C60 cathode interlayer has three functions: (i) improving the diode temporal response; (ii) suppressing the dark current; and (iii) controlling the spectral response. Hence, the performance of the photodiode was greatly enhanced without compromising the LDR. Similarly, hole transport layers can also be employed to reduce the dark current and control the spectral response.[90]
Besides being charge transport layers in photodiodes, organic semiconductors are widely applied in photoconductors. PCBM was applied to perovskite hybrids in order to fabricate performance-enhanced photoconductors or phototransistors via enhancing the charge transfer.[169,170] Yang and co-workers fabricated a flexible and air-stable perovskite photoconductor based on the MAPbI3/dioctylbenzothieno [2,3-b] benzothiophene (C8BTBT) bulk heterojunction;[167] the schematic device structure is exhibited in Fig. 9(c). The organic semiconductor C8BTBT has been fabricated via a simple, one-step solution process. Compared with pure MAPbI3, the responsivity of hybrid-structure PDs was promoted by almost one order of magnitude (Fig. 9(d)). Furthermore, the hybrid-structure PDs held unique advantages of stability and flexibility. Due to the incorporation of C8BTBT, 70% of the original performance could be maintained after exposure to ambient conditions for 50 days without any encapsulation, and the photocurrent exhibited a decrease of less than 5% as the devices were bent for 10000 cycles at a small radius of 7.5 mm. In addition, poly(diketopyrrolopyrrole-terthiophene) (PDPP3T)[171] and rhodamine B[172] were also applied in hybrid-structure flexible perovskite PDs.
4.1.3. Metal oxidesMetal oxides have been widely applied in perovskite optoelectronic devices as charge transport layers due to their suitable energy levels and high mobility.[21,173] Metal oxides can also be applied in perovskite PDs for the following reasons: (i) providing a mesoporous scaffold for perovskites; (ii) providing a high efficient charge transfer layer; (iii) band gap engineering; (iv) providing surface passivation; and (v) providing a blocking layer to reduce the dark current. Mesoporous TiO2 was not only applied in perovskite to provide a mesoporous scaffold for perovskites, but also in perovskite photodiodes. Tress and co-workers fabricated high-gain, low-voltage MAPbI3 PDs based on FTO/TiO2 MP scaffold/MAPbI3/Spiro-MeOTAD HTM/Au (FTO: fluorine-doped tin oxide; MP: mesoporous; HTM: hole transporting material), which showed the highest responsivity of
under 550 nm illumination.[174] Wang and co-workers reported a self-powered, UV–vis perovskite PD based on TiO2 nanorods/MAPbI3.[41] The TiO2 in PDs not only provided a mesoporous scaffold for perovskites as mesoporous TiO2, but also fitted the energy level alignment. In addition, ZnO nanorods[175–178] also provided a mesoporous scaffold for perovskites. Zhang and coworkers reported an inorganic perovskite–ZnO heterostructure perovskite photoconductor.[35] Owing to the interfacial charge transfer from perovskite to the ZnO layer, the responsivity and detectivity were largely enhanced. Additionally, flexible PDs based on CsPbBr3/ZnO demonstrated excellent stability and outstanding flexibility. TiO2 in the perovskite mentioned above[168] also matched the energy levels of ITO and PCBM, and enhanced the charge transfer efficiency. Choy and co-workers introduced a room temperature solution-processed NiOx:PbI2 hole transport layer into MAPbI3 perovskite-based PDs.[179] The NiOx:PbI2 layer passivated the surface of the perovskite, and offered a large electron injection barrier at the ITO interface for suppressing dark current. Besides, the favorable energy level alignment with perovskite film also enhanced the hole extraction. Metal oxides can also act as a blocking layer in the perovskite photodiode. The dark current can be suppressed by adding an Al2O3 layer.[33]
Recently, amorphous indium gallium zinc oxide (IGZO) has become an attractive channel material for organic–inorganic hybrid phototransistors.[180] The advantageous features of IGZO, such as high field-effect carrier mobility and low-temperature large-area processing capabilities, make it possible to apply it in perovskite transistors. With an optical bandgap of about 3 eV, amorphous IGZO is ready to sense ultraviolet light with wavelengths shorter than 420 nm. Zhou and co-workers developed a hybrid phototransistor where IGZO was capped with a solution-processed perovskite layer.[181] The device structure of the hybrid phototransistor is depicted in Fig. 10(a). To obtain a low dark current, the morphology of the perovskite layer is prepared to be a needle-like film rather than a smooth, compact perovskite thin film. Although the responsivity and detectivity of IGZO transistors were relatively higher than that of the MAPbI3-capped IGZO transistors, the latter were highly sensitive to light in both UV and visible regions (Fig. 10(b)). Since the IGZO layer is usually very thin, it introduces a new way for fabricating flexible perovskite phototransistors.
4.1.4. Quantum dotsThe perovskite quantum dots have been discussed above; however, there are various materials that can be processed into CQDs, such as graphene, PbS, PbSe, HgTe, and CdSe/ZnS. They have been widely applied in PDs due to their ability to limit spectral absorption and offering a wide range of bandgaps.[32,127,128,182–184] It is advisable to combine the perovskite with CQDs of other materials to enhance the performance of PDs. Gong and co-workers fabricated MAPbI3/PbS QDs hybrid perovskite photodiodes, in which PbS QDs induced an additional trap-state onto the surface of the MAPbI3 film, thus forming ohmic contact at the MAPbI3/aluminum (Al) interface.[185] As a result, the photodiodes based on hybrid perovskite achieved an EQE of ∼4500%, a responsivity of
, and a detectivity of over 6×1013 Jones at a small bias of 2 V. Zhang and co-workers demonstrated a transistor based on the MAPbI3 perovskite/PbSe CQD heterostructure.[46] The architecture of the phototransistor is shown in Fig. 10(c). The perovskite thin film with a PbSe quantum dot active channel was made by a two-step spin-coating method. PbSe CQDs have a significant absorption capacity for near infrared (NIR) and short-wavelength light, which cannot be accessed by perovskites. Thus, the phototransistor exhibits a wide spectral response ranging from 300 nm to 1500 nm and relatively high responsivity (Fig. 10(d)). In addition, Yang and co-workers blended ternary PbSxSe1−x quantum dots with MAPbBr3 quantum dots to fabricate broadband photodiodes.[186] The photodiodes ITO/ZnO/PbS0.4Se0.6:MAPbBr3/Au exhibit a maximum responsivity and specific detectivity of
and 3.59 ×1013 Jones, and
and 3.70 ×1013 Jones at room temperature under a 532 nm laser (
) and 980 nm laser (
), respectively.
4.2. Interface/band gap engineeringLayers are stacked together in a vertical perovskite device, producing several interfaces and interfacial regions. Hence, the interfaces and band alignment have significant influences on the charge processes in addition to the qualities of the layers themselves. As a result, interface engineering and band alignment engineering have become effective ways to promote the performance of perovskite PDs, especially the photodiodes.
Sargent and co-workers produced a thin, pinhole-free compact layer of Al2O3 on the nanostructured TiO2 to passivate the surface trap states, and further added a thin layer of PCBM to minimize the dark current.[33] Zhang and co-workers introduced interface engineering to improve the responsivity and response speed of the perovskite photodiode by replacing the TiO2 transport layer with a SnO2 layer, and reduced the dark current by adding an inter-layer of poly(vinylpyrrolidone) between the electron transport layer and perovskite layer. The SnO2 layer has a lower conduction band and lower trap density when compared with TiO2 layer, thus leading to a better band alignment and a more efficient carrier transport.[34] Besides, organic semiconductors and 2D materials were also involved in the interface/band gap engineering of perovskite PDs. Huang and co-workers fabricated high-performance perovskite PDs with ingenious device design, in which the
-bis[(p-trichlorosilylpropyl-phenyl)phenylamino]-biphenyl (TPD–Si2) serves as the hole transporting/electron blocking layer (Fig. 11(a)).[31] There are abundant defects/traps on the surface of perovskite, which are detrimental to the performance of photovoltaic devices. However, it is possible to exploit traps to boost the performance of perovskite PDs. When introducing an electron transport layer between ITO and the perovskite layer, the ITO/BCP(C60)/MAPbI3/MoO3/Ag device showed photovoltaic I–V curves. Whereas, benefiting from the trapped hole-induced electron injection, the MAPbI3 PD (device shown in Fig. 11(a)) worked as a photodiode in the dark and showed a large photoconductive gain of ∼489 at a very low driving voltage of −1 V under illumination. Thus, the photocurrent of MAPbI3 PD was more than 100 times larger than that of the reference photovoltaic device (Fig. 11(b)). For the MAPbI3 PD, there were large energy barriers for carriers injecting into the perovskite layer, which explained the rectification behavior in the dark. However, when the device was illuminated, one type of trapped charge in the MAPbI3 active layer induced band bending in the perovskite layer close to one of the electrodes. Thus, the Schottky junction thickness was reduced, which allowed the injection of the opposite charges under reverse bias (Fig. 11(c)). This work also provided a novel approach to introduce the photoconductive effect to a vertical PD by interface/band gap engineering.
Sum and co-workers introduced a vacancy-engineered MoS2 monolayer to achieve ultrafast hole transfer at the interface of MoS2 and perovskite.[187] It was found that creating S vacancies in MoS2 strongly improves the hole transfer rate between MAPbI3 and MoS2 layers. Importantly, this work highlights the feasibility of applying defect engineering in tuning the band alignment of 2D transition metal dichalcogenides (TMDCs)–perovskite hybrid PDs. Sun and co-workers inserted Au-NPs into MAPbI3/graphene hybrid PDs to achieve a significant responsivity enhancement.[37] The schematic of the device structure is illustrated in Fig. 11(d). Au-NPs were bonded on the Si/SiO2 substrate with a Au source and drain electrodes through a self-assembled monolayer of 3-aminopropyl-triethoxysilane. The responsivity and EQE of the MAPbI3–graphene–Au-NP hybrid PD (P–G–Au PD) are almost two times higher than those of the device without Au-NPs (Fig. 11(e)). The responsivity decreased with illumination intensity due to the increased probability of carrier recombination as the carrier density increases. For P–G–Au PDs, most photo-induced carriers were generated around the interface between graphene and perovskite due to the near-field enhancement of Au-NPs. Thus, the recombination of photon-generated carriers was smaller than that of carriers generated far from this interface (Fig. 11(f)). As a result, the carrier extraction efficiency and response speed were improved, which demonstrated a promising strategy to improve the performance of graphene-based PDs.
4.3. Flexible PDsFlexible PDs have been widely applied in wearable devices, stretchable displays, and electronic skins due to their reduced cost and light weight.[188–190] Fortunately, perovskites can be prepared by solution processing, which renders the possibility for them to be assembled into flexible PDs. In addition to the perovskite itself being compatible with flexible PDs, we have discussed several strategies to fabricate a flexible PD based on perovskites, including reducing the dimensions of bulk perovskite and integrating them with 2D materials and organic semiconductors. As we mentioned in Section 3.1, Xie and co-workers first demonstrated the flexible perovskite PD through a low-cost, solution-processed, and self-assembly strategy on an ITO/PET substrate.[47] The device exhibited high sensitivity and fast response speed. Importantly, the photocurrent remained nearly unchanged under different bending states or 120 cycles of bending, which indicated the extreme flexibility, good folding endurance, and electrical stability of the device. In addition, similar flexible PDs based on pure perovskite polycrystalline film can also be processed by a vapor–solution method.[84] Besides thin film, there are other forms of pure perovskites that can be applied in flexible devices, such as nanowires, networks, nanosheets, and nanoflakes.[118,143,146] Song and co-workers reported flexible PD arrays based on uniform perovskite networks synthesized on PET by controlling the crystallization.[118] The uniform intersecting ribbon-like crystal network (Fig. 12(a) and inset) demonstrated good uniformity and transparency compared to thin films and nanowires, combining the advantages of thin films and nanowires. Figure 12(b) shows the schematic diagram of the individual device structure (top) and network PD array (bottom). The poly(methyl methacrylate) (PMMA) layer was deposited to form a sandwich structure (PET/perovskite/PMMA), which greatly improved the device stability so that the network PD arrays could be easily kept intact for one month of storage in air. The photocurrent shrank less than 10% after 10000 bending cycles at a fixed angle of 40° (Fig. 12(c)), which indicated superior flexibility and stability of the devices.
For hybrid perovskite flexible PDs, the perovskite was usually hybridized with organic semiconductors, such as C8BTBT, PDPP3T, PCBM, single-walled carbon nanotubes (SCNTs), and rhodamine B.[167,171,172,191,192] Shi and co-workers reported a flexible broad-band PD based on a bilayer composite film of MAPbI3/PDPP3T.[171] The fabrication process is illustrated in Fig. 12(d). Perovskite and PDPP3T solutions were successively dropped onto the PET substrate with interdigitated gold electrodes. Since PDPP3T is a narrow band gap-conjugated polymer, the absorption spectrum of the pristine PDPP3T has a dominant band centered at 838 nm and a slightly weaker shoulder band with a peak at 763 nm located outside the spectral coverage of the MAPbI3 absorber (Fig. 12(e)). However, the MAPbI3/PDPP3T hybrid film has complementary absorption in the 550–940 nm region, so it is promising for the fabrication of a UV–vis–NIR PD. Hence, the responsivity of the flexible hybrid PD was significantly enhanced. The responsivity of the hybrid PD at 650 nm or 835 nm was measured to be 90% or 85% after 1000 cycles of bending/straightening to a curvature radius of 7 mm (Figs. 12(f) and 12(g)). Huang and co-workers fabricated a flexible MAPbCl3/SCNT hybrid PD,[191] which presented a high responsivity
) to UV light at an intensity of
, and almost no response to visible light. Combined with the comparable electrical and photosensitive properties of the MAPbBr3/SCNT hybrid PD, a series of flexible devices applied to distinguish UV, visible, and IR spectra were attained. In addition, several materials mentioned in Section 4.1 were also compatible with the flexible devices, and low-dimension materials as well as soft organic semiconductors would be good choices for fabricating a flexible hybrid PD.
4.4. Narrowband PDsNarrowband PDs used for spectrally selective photodetection are widely required in imaging. Spectral discrimination in state-of-the-art narrowband PDs is usually realized by one of several approaches: (i) by combining broadband PDs with bandpass filters,[193] (ii) by using photoactive materials with narrowband absorption,[194] (iii) by intentionally enhancing absorption in a particular wavelength range via the plasmonic effect,[195] and (iv) by splitting the light into its component colors.[196] Perovskites have good prospects for application in narrowband PDs due to the controllable band gap, large carrier diffusion length, and large absorption coefficient. These unique properties also extend the strategies to carry out the device engineering for narrowband perovskite PDs.
The vertical PDs based on single-crystal perovskite are well suited for narrowband PDs, which has been discussed in Section 3.2. Meredith and co-workers reported red, green, and blue filterless narrowband visible photodiodes, all with a FWHM of
.[101] The working principle of narrowband PDs was a charge collection narrowing (CCN) mechanism, which had been discussed in detail by Burn and co-workers.[197] The photodiode architecture is shown in Fig. 13(a) and inset, in which a photoactive layer (perovskite) is sandwiched between a transparent anode (ITO/PEDOT:PSS) and cathode stack (C60/LiF/Ag). The CCN is realized because the junction has a high optical density and long transit time for photogenerated carrier extraction. There are three different absorption regimes: high α, where the incident light intensity falls off exponentially within the junction (the Beer–Lambert regime); low α, where the incident light propagates within the junction and is subject to interference (the cavity regime); and α=0, where the incident light is almost not absorbed. Considering that the surface-generated carriers will be subject to significant recombination losses due to the higher local carrier concentration and imbalanced transit times for the electrons and holes, the charge collection efficiency will be suppressed and result in a low EQE in the Beer–Lambert regime. Figure 13(b) shows the optical field distributions in the red narrowband photodiodes for four wavelengths, in which the
photons cannot penetrate the whole film, carriers are surface-generated, and the
photons can penetrate the film and photocarriers are volume-generated. In addition, the narrowband response can be pushed out into the NIR, and the FWHM can be tuned further (from ∼40 nm to 200 nm) by changing the halide ratio (Fig. 13(c)). The CCN principle has been widely applied to fabricate narrowband perovskites.[36,198] In particular, Bakr and co-workers fabricated a PD operating in both broadband (upon bottom illumination) and narrowband regimes (upon top illumination), which was realized due to the combined effect of CCN and a surface-located polycrystalline film.[19]
Based on the common practice of combining broadband PDs with bandpass filters to achieve narrowband detection, Huang and co-workers demonstrated a new method to tune the spectral response band of perovskite PDs with perovskite filters.[199] They prepared two types of devices, the working principle schematic diagram of which is exhibited in Fig. 13(d). The perovskite photodiode with a thick active layer operates based on using the same material as both the filter and active layer. The perovskite photodiode combining a thick perovskite layer as an optical filter in front of light incident window operates based on the common practice of combining broadband PDs with bandpass filters, in which the long wavelength light is filtered by the perovskite-1 layer. The schematic device structures of two types of narrowband perovskite PDs are shown in Fig. 13(e), in which the perovskite-1 layer denotes MAPbBr3−xIx, and the perovskite-2 layer denotes neat MAPbI3. The EQE spectrum shows that using mixed-halide perovskites as the perovskite-1 layer is more efficient than using neat MAPbI3 as both the filter and active layer (Fig. 13(f)). In a similar way, the perovskite can also be applied in narrowband PDs based on non-perovskite material as a filter layer.[200]
5. Conclusion and perspectivesIn summary, we introduce and discuss perovskite PDs in terms of chemical compositions, material morphologies, device architectures, and engineering strategies. The use of perovskites in PDs is compelling due to their unique electric and optical properties, simple and low-cost processing, and mechanical flexibility. There have been various strategies for synthesizing perovskites, such as solution processing, the EISA method, and chemical vapor deposition. Several types of perovskite materials for PDs have been demonstrated, including polycrystalline films, single crystals, nanowires/nanorods, quantum dots/nanocrystals, and 2D/quasi-2D perovskites. PDs based on various perovskite materials possess very different merits regarding photoelectric performance. The key parameters of perovskite PDs are listed and compared in Table 2. Polycrystalline films are most widely used because they are easy to fabricate by solution methods and are compatible with different PD configurations. However, vast trap sites that exist in the grain boundary and interface limit the performance of PDs, which get a valid settlement by the single-crystal and low-dimensional perovskites such as nanowires, nanoplates, and nanosheets. In particular, perovskite single crystals and nanocrystal/quantum dots are appropriate for narrow-band PDs and flexible PDs, respectively. Perovskites with novel morphology were also reported to improve the performance of PDs. Single-crystalline layered perovskite nanowires are fabricated, in which insulating organic cations and conductive inorganic frameworks are self-organized layer-by-layer along the nanowire length.[201] This creates high resistance in the interior of the crystals and high conductivity at the edges of the crystals. The ultra-high responsivity (
) and detectivity (
Jones) of the PD originate from a combination of efficient free-carrier edge conduction and resistive hopping barriers in the layered perovskites. A new inorganic perovskite film via a vapor deposition method using a dual-phase inorganic material (CsPbBr3–CsPb2Br5 mixed phases) was proposed to further improve the quality of perovskites.[202] The CsPb2Br5 provided self-passivation, which was similar to the PbX2 passivation in the hybrid perovskite.[11,203] Thus, the recombination of the charge carriers was reduced, and the stability of the inorganic perovskite was enhanced. Other processing methods such as spray-coating, ink-jet printing, and electrospinning may also have great prospects in fabricating perovskites.[190,204,205]
In terms of the device engineering of perovskite PDs, the core issues are different for the three types of PDs (photodiodes, photoconductors, and phototransistors). For perovskite photodiodes, the universal strategies to enhance the performance were introducing an interlayer to regulate the energy band and passivate the traps on the interface, which could suppress the dark current and boost the photocurrent. For perovskite photoconductors, it is pivotal to increase the gain of the device. According to Eq. (4) in Section 2.1.1, the gain G of PDs is determined by the excess minority carrier lifetime τ, channel length L, and the carrier mobility of the active layer μ. In consequence, low-dimensional perovskites possess advantages due to their small size, which means a smaller channel length. The carrier lifetime τ can be prolonged by hybridizing perovskite with materials that possess shallow defects, which could trap one type of the photogenerated carriers.[27] Meanwhile, perovskite phototransistors are engineered based on photoconductors. Generally, graphene was applied to enhance the performance of perovskite phototransistors.[45,138,158] The gain of the phototransistor can be remarkably increased by the photogating effect, which arises from the graphene–perovskite interface.[45] TDMs are also promising to be widely applied in hybrid perovskite phototransistors due to their similar electrical and mechanical properties.[161] In addition, h-BN was also adopted to be a substrate preserving the intrinsically high mobility of graphene,[162] or as an effective protection for perovskite to significantly extend the lifetime of the device.[206] Although impressive advances have been achieved by the various device engineering strategies discussed above, there are still several shortcomings that limit the development of perovskite PDs. (i) These PDs are usually operated at a high bias voltage, which leads to a large dark current and limits the detectivity of devices. The dark current can be suppressed by an interlayer or interfacial modification. In addition, self-powered perovskite PDs also facilitate application of the PDs at a low driving voltage or in a weak light.[39,207–210] (ii) Because of the wide energy band gap of Pb-based perovskites, most perovskite PDs usually have weak responsivity to NIR light. By replacing Pb with Sn or alloying the materials with Sn, absorption in the NIR range can be enhanced.[211–214] However, the structure of perovskites is ruined in air due to the easy oxidation of Sn2+ to Sn4+. To enlarge the response of the PDs in the NIR range, a broadband PD based on the MAPbI3/PbSe quantum dot heterojunction that has a wide spectral response spectrum ranging from 300 nm to 1500 nm was fabricated.[46] In addition, recent research revealed that upconversion[215,216] and two-photon absorption[217] contributed to the response in the NIR region. (iii) The instability problem has yet to be solved. On the one hand, perovskites with mixing of MA+, FA+, and Cs+ are shown to be more thermally and structurally stable than the pure perovskites.[62,63] On the other hand, the 2D perovskites have been reported to have a better moisture stability than 3D perovskites;[74,148] recent studies on perovskite solar cells also revealed that 2D/3D perovskite compounds showed outstanding thermal and moisture stability.[218–220] These results are beneficial to guiding the processing of perovskites with long-term stability. (iv) The toxicity of Pb-based perovskites is still hard to overcome because Pb is indispensable for achieving high performance in perovskite optoelectronics. Although great effort has been made in Pb-free perovskite photovoltaics,[66] there is still a long way to go to apply the lead-free perovskites to PDs and improve the photoelectric conversion efficiency of Pb-free perovskite optoelectronics. Above all, additional research efforts should be focused on fully understanding the properties and resolving the aforementioned bottlenecks in order to promote the performance of future devices.