1. Introduction
Given the emergence of electronics on skin/organs, rollable displays, printed radio-frequency identification (RFID) tags, electronic papers and wearable sensor, as well as the printability and potential in realizing low-cost and large-area electronic devices, devices with flexible and stretchable organic field-effect transistors (OFETs) have attracted significant attention in the development of next-generation thin-film electronics [
1,
2].
In fact, one of the major challenges for OFETs has been the rather high voltages needed for their operation when the conventional SiO
2 is used as the gate dielectrics, which is considered to suffer from its low dielectric constant (k~3.2) [
3]. In order to reduce the operating voltage of OFETs, it is necessary to use a high k material and/or to reduce the thickness of the gate dielectric layer [
4,
5]. However, when the SiO
2 thickness is reduced to a nanoscale, the gate leakage current derived for the tunneling effect increases exponentially [
6]. Although some high-k metal oxide can achieve higher current switch and migration rate, the vacuum and high temperature conditions which are needed for the preparation of inorganic dielectric layer greatly increase manufacturing costs and are unsuitable for flexible plastic substrates. Polymer dielectrics usually afford excellent mechanical flexibility and are compatible with inexpensive plastic foils since they can be processed by coating or printing techniques at low temperatures, but polymers generally have low k, which makes it difficult to meet the requirements for high-density charge storage [
7,
8,
9]. Therefore, the growing appeal in new dielectric materials has arisen primarily from the necessity for an inexpensive device fabrication process and the reduction of the operating voltages required for new flexible/printed electronic technologies [
10,
11,
12].
Polymer/ceramic nanoparticle composite materials have been considered one of the most promising materials for capacitors, since they generally have outstanding electronic properties deriving from the synergy between the two phases, that is the high dielectric permittivity of pure ceramic hosts and the good mechanical strength and ease of film casting of polymer materials. The combination of a solution-processable high dielectric constant BaTiO
3 or BaSrTiO
3 nanoparticle layer and other polymers for low-operated organic electronics were reported [
13,
14,
15]. Calcium titanate (CaTiO
3) ceramics are known as an excellent insulating material with high dielectric constant (k~150) [
16], however, no full study of their role as the gate dielectric has been carried out, particularly for flexible electronic applications.
In this work, we describe the synthesis of ceramic material calcium titanate nanoparticles (CaTiO3 NPs) and introduce the novel CaTiO3 NPs into crosslinked poly(4-vinyl phenol) (PVP) polymer via simple solution-processing methods. Furthermore, by spinning an additional thin film of PVP, this provides a suitable surface characteristic with a low surface roughness and appropriate surface energy for semiconductors and high dielectric strengths that minimize the leakage current through the gate insulator. Consequently, we fabricate low-voltage operated flexible OFETs with good performance and stability.
2. Materials and Methods
2.1. Materials Synthetic
Calcium titanate nanopowder is made in the lab. We took 3 mL glacial acetic acid in the high-pressure reaction kettle, and then dissolved butyl titanate (0.3 mL), distilled water (3 mL), CaCl2 solution (1 mL, 1 mol/L), an appropriate amount of PVA solution (4 g/L) and NaOH solution (5 mol/L) in the reaction kettle under stirring. We kept adding distilled water until total volume reached 40 ml. We sealed it after stirring evenly, and put it in an oven for chemical reaction at room temperature for a period of time as a subsequent step. The precipitate produced by the above steps was centrifuged and dried at 60℃ to obtain the CaTiO3 nanopowder sample.
PVP (polyvinyl phenol, Mw~25,000) with 20 wt% and poly (melamine-co-fomaldehyde) (MMF) with 10% were dissolved in propylene glycol monomethyoether acetate (PGMEA) for use. The MMF was herein used as the cross linker of PVP to remove the hydroxyl groups of PVP. After 4 hours of magnetic stirring at room temperature, CaTiO3 nanopowder (3 wt%) was mixed with PVP solution and treated with ultrasonic waves at room temperature for 10 hours to make the particles fully disperse evenly. In order to remove agglomerated particles, the solution was centrifuged at 3000 r/min for 10 min. After that, the precipitate was removed to obtain the PVP: CaTiO3 NPs mixture solution. The sample solution for experiments was subsequently filtered with a PTFE filter (0.22 um aperture) to exclude a few remaining larger particles.
Glacial acetic acid, butyl titanate, CaCl2, NaOH were received from Aladdin (Shanghai, China). PVA, PVP, MMF, PGMEA were received from Sigma Aldrich (Beijing, China), distilled water was made by Milli-Q Direct16.
2.2. Device Fabrication
The schematic structure of the fabricated OFET devices is shown in
Figure 1. They have a bottom-gate, top-contact structure fabricated on a PI (polyimide) substrate. Initially, 100 nm thick aluminum (Al) serving as the gate electrode were deposited by thermal evaporation on the PI substrate which was treated with ultraviolet (UV) ozone for 5 min; ~300 nm thick film of PVP solution and PVP:CaTiO
3 nanoparticles mixture solution were deposited on different substrates by spin coating respectively, followed by an annealing process at 120 ℃ for 4 h to produce thermal-crosslinking. For comparison, a thin film of PVP(~50 nm) was additionally spin-coated onto the PVP:CaTiO
3 nanocomposites to optimize the dielectric layer.
Afterward, the n-type pentacene (≥99.995% trace metals basis, Sigma Aldrich, Shanghai, China) (~40 nm) was then deposited at a rate of approximate 1 Å/s under a background pressure of 10−4 Pa. Gold (Au) (~50 nm) source and drain contacts were deposited by thermal evaporation through a shadow mask. The width and length of the device channel were defined as 900 and 90 μm, respectively.
2.3. Characterization
Crystal phase structures of the CaTiO3 nanopowder and pentacene were characterized by an MiniFlex 600 X-ray diffraction (XRD) instrument (Rigagu, TKY, Japan) over the 2θ of 10°to 80°. Electrical characteristics (capacitance vs. voltage, current vs. voltage) of OFETs were performed by a Keithley 4200-SCS semiconductor parameter analyzer (Tektronix, Johnston, OHIO, USA), whereby all electrical measurements were carried out in air. The surface morphologies of the dielectric films and pentacene were characterized with an SPI 400 atomic force microscope (HITACHI, TKY, Japan) in tapping mode. The surface energies of insulators were established by measuring the contact angle using a Kino SL200 KS goniometer. Film thickness was tested by Tencor D-100 step profiler (KLA, Milpitas, CA, USA). During the interval of the bending test, the device is kept bent (50 mm) and placed in a glove box filled with nitrogen to avoid the influence of water and oxygen in the air on the pentacene.
3. Results and Discussion
No heterophase diffraction peaks were found in the XRD pattern of calcium titanate (
Figure S1), indicating that the nanometer powder prepared in the lab presents a typically pure phase. The mixed solution was stationary for 1 week without precipitation (
Figure S1, inset), CaTiO
3 NPs can be dispersed well in cross-linking PVP solution with uniform size.
In an OFETs device, the charge density (Q = CV) localized at the first few semiconductor monolayers close to the interface is proportional to the dielectric constant [
11,
17].
Figure 2 illustrates a parallel-plate metal–insulator–metal (MIM) capacitor that is used to measure the dielectric properties of materials.
Figure 2a presents representative frequency-dependent areal capacitance curves for a high-k and a low-k dielectric [
8]. It indicates that the addition of calcium titanate ceramic nanoparticles increases the capacity of the dielectric layer. It falls significantly at higher frequencies in the PVP:CaTiO
3 NPs and PVP:CaTiO
3 NPs/PVP devicea, since the polarization behavior of high-k materials is different in various frequency ranges, and some polarization cannot follow the change of the high-frequency electric field [
18]. The dielectric properties containing PVP layers filled with various concentrations of CaTiO
3 NPs are shown in
Figure 2b, the leakage current density increases as the proportion of CaTiO
3 NPs increases, which is attributed to the gap between the nanoparticles and the polymer. Due to the modification of thin PVP, the leakage of the capacitor is obviously improved.
The electrical performances of OFETs based on various dielectrics are investigated in sequence. The output and transfer characteristics of the devices are presented in
Figure 3. It can be seen that the electrical properties of the devices based on different dielectrics vary significantly, including threshold voltage (V
th), on-off ratio (I
on/I
off) and subthreshold slope (SS). The detailed electrical parameters of three types of OFETs are listed in
Table 1. The drain current of device composed of PVP insulator filled with 3 wt% CaTiO
3 NPs is higher than that of devices with a pure PVP dielectric layer. It can be attributed to the large two-dimensional charge density induced in the transistor channel as a result of the high capacitance of the CaTiO
3 NPs-filled PVP insulator. The more the charge carriers are accumulated at the interface between organic semiconductor and dielectric, the easier the channel could be got through at a lower voltage [
19]. Therefore, the use of high-k CaTiO
3 NPs causes high density charge carriers that result in the reduced V
th from –10.5 V to –2.9 V. However, due to the addition of nanoparticles, the gap between the particles and the polymer leads to the increase of leakage current, and the hysteresis is serious (I
on/I
off = ~10
3, SS = 8.3 V/dec). After being modified by thin PVP, the related performances are dramatically enhanced, achieving the highest I
DS and favorable I
on/I
off value which gains an increase of nearly two orders of magnitude, and its leakage current reverts to a lower current (
Figure S2). Moreover, the modified device obviously promotes its carrier mobility (μ) from 0.12 cm
2/Vs
−1 to 0.29 cm
2/Vs
−1, and exhibits a relatively steeper threshold slope (SS) of 0.8 V/decade as compared to that of the unmodified devices, which is due to the reduction of the surface states and charge traps at the contact interface [
20].
In order to further illustrate the effect of the improved dielectric layer. The test of the AFM and water angel contact is carried out. As shown in
Figure 4, the pentacene could grow in an orderly way on flat PVP film with large grain size, while the roughness of the film increases after mixing with high k CaTiO
3 NPs, resulting in the smaller and discontinuous grain size of the pentacene grown. The increased roughness reduces the carrier mobility of the associated device because of the increased barrier, which limits the hopping of charges in the channel region [
21]. After PVP thin-film modification, fewer upheavals can be seen on the surface that lead to the surface roughness and surface energy of the dielectric layer decreasing, reducing from 1.07 nm, 43.9 mN/m to 0.79 nm, 38.6 mN/m, respectively. It gives rise to the increase of the grain size and the decrease of the grain boundary, since the smoother and hydrophobic surface.
XRD tests were performed for the growth of pentacene on different dielectric layers. As depicted in
Figure 4d, a sharp diffraction peak appears at 2θ = 5.66°, which corresponds to the (001) crystal plane of pentacene. Based on the data of the (001) diffraction peaks, the average pentacene crystallite sizes were calculated by Scherrer’s formula [
22]. They were 42 nm, 25 nm, 35 nm for samples with dielectric of PVP, PVP:CaTiO
3 NPs, PVP:CaTiO
3 NPs/PVP, respectively. The diffraction peak intensity of (001) direction of pentacene grown on the surface of PVP:CaTiO
3 NPs film was lowest, and the corresponding grain size was smallest. After being coated with a thin PVP layer, diffraction peak intensity increased, achieving the larger pentacene.
To investigate the suitability of the device in flexible applications, we evaluated the transistor properties in a compressed state and influence of curvature on device electrical performance; a fixture was used to bend the device and adjust the different curvature to test the electrical performance, as shown in
Figure 5a. The distance between the fixtures is defined as the bending diameter (initial, 70 mm, 50 mm, 30 mm, respectively).
Figure 5b shows the transfer characteristics of the flexible OFETs devices based on PVP:CaTiO
3 NPs/PVP composite dielectric when bending at various diameters. As the bending diameter becomes smaller, the threshold voltage of the device is shifted to the negative direction of the X-axis, from –2.9 V to –3.2 V in bending diameter at initial, 70 mm, 50 mm, repectively. The corresponding current on/off ratio (I
on/I
off) has negligible change (~10
5). While it is bent at 30 mm diameter, V
th obviously increases to –6.1 V, and current on-off ratio worsens. Particularly, the devices could not function at the further bending compression (10 mm) because of the current breakdown. This is ascribed to the fact that bending widens the spacing between pentacene molecules, where carrier transmission is blocked. Accordingly, V
th increases. While applying excessive bending pressure, the related device is subjected to a widening gap between the polymer and ceramic nanoparticles, resulting in a sharp increase in leakage current through the gate.
Moreover, the effects of the mechanical stress on the OFETs characteristics were examined by continuously bending stress for 120 hours at a bending diameter of 50 mm (see in
Figure 5c and inset). It can be seen that the changes in mobility and V
th in the linear region are negligible during a constant bending stress, indicating good bending stability.