DOI:
10.1039/D3RA03063F
(Paper)
RSC Adv., 2023,
13, 20575-20583
Ultrasensitive sensing performances of amphiphilic block copolymer induced gyrus-like In2O3 thick films to low-concentration acetone
Received
8th May 2023
, Accepted 24th June 2023
First published on 10th July 2023
Abstract
In the present work, an inducible assembly of di-block polymer compounds approach was employed for the synthesis of mesoscopic gyrus-like In2O3 by using lab-made high-molecular-weight amphiphilic di-block copolymer poly(ethylene oxide)-b-polystyrene (PEO-b-PS) as a revulsive, with indium chloride as an indium source and THF/ethanol as the solvent. The obtained mesoscopic gyrus-like In2O3 indium oxide materials exhibit a large surface area and a highly crystalline In2O3 nanostructure framework, and the gyrus distance is about 40 nm, which can facilitate the diffusion and transport of acetone vapor molecules. By using this material as a chemoresistance sensor, the obtained gyrus-like indium oxides were used as sensing materials, showing an excellent performance to acetone at a low operating temperature (150 °C) due to their high porosity and unique crystalline framework. The limit of detection of the thick-film sensor based on indium oxides is appropriate for diabetes exhaled breath acetone concentration detection. Moreover, the thick-film sensor shows a very fast response–recovery dynamics upon contacting acetone vapor due to its abundant open folds mesoscopic structure, and also to the large surface area of the nanocrystalline gyrus-like In2O3.
1. Introduction
Acetone is widely used in many fields of industrial production because of its chemical activity, which is considered as one of the important raw materials, solvents and combustible gases.1,2 In addition, in human breath there are hundreds of species of volatile organics which are exhaled from the blood through breath in the lungs. Expiratory analysis has attracted much attention among potential diagnostic techniques because of its noninvasive and real-time diagnostic advantages. In the breath of healthy people, the average concentration is below 0.9 ppm, while in diabetics, it is usually above 1.8 ppm.3–8 Therefore, acetone can be used as a good biomarker for detecting diabetes in breath analysis. In order to detect diabetes mellitus by using an exhaled gas sensor, it is required that gas sensing material should show a large response under the condition that the concentration of acetone is very low, especially in a humid environment and under a complex background gas with different oxygen concentrations.
Many binary oxides or their composites (such as SnO2,9–12 ZnO,13–16 WO3,17–19 NiO,20,21 Fe2O3,22,23 Co3O4,24 TiO2,25–28 CuO–ZnO,29 and ZnO–In2O3 (ref. 30)) have been found to be useful as acetone sensors. In recent years, indium oxide-based gas sensing materials have attracted extensive attention in the detection of low-concentration acetone gas. Gas sensors based on indium oxide and its derivatives react well to acetone. Different oxide morphologies (such as thick film, thin film, nanoparticles, bulk) have a great influence on the gas sensing performance of gas sensors.31–40 In addition, the response to various reducing gases can be improved by compounding certain materials in inorganic oxides and perovskite oxides, such as LaFeO3, SmFeO3, NdFeO3, Yb2Fe3O7, CdSnO3, La1−xPbxFeO3 etc.41–54 In addition, lots of efforts have been made in order to synthesize highly effective indium oxide to improve the performance of In2O3-based nanomaterials and devices with different morphologies and sizes to promote the guest gas molecules' diffusion. Meanwhile, increasing the surface area provides abundant exposed active sites for kinds of interface adsorption, electron transport, reactions and host–guest interactions.
Different forms of In2O3 nanostructures which have various forms and morphologies, such as nanosheets, nanowires, nanospheres, nanotubes, nanoflowers, and layered nanostructures, are prepared by hydrothermal and solvothermal preparation of In(OH)3 or InOOH,55–59 followed by calcination treatment. Methods of electrospinning, chemical vapor deposition, polymer templating, laser ablation, self-templating etc. can also be used to prepare large specific surface area In2O3 nanocrystalline materials.60–70 Acetone sensing properties for various semiconductor sensors are shown in Table 1. However, the above methods often result in ill-defined convoluted structures and uncontrolled morphology and porosity. It was found that these materials have remarkable electrochemical and gas sensing properties due to their large specific surface area and interconnected mesoscopic structure. In addition, the induction synthesis method for the inducer is more suitable and flexible for the production of high-performance sensing materials with large surface area. However, due to the difficulty in controlling the self-assembly and crystallization process of organic templates and inorganic precursors, there are few studies on the synthesis of sensing materials with high sensing efficiency and large surface area by flexible soft template-induced synthesis.
Table 1 Acetone sensing properties for various semiconductor sensors
Author |
Materials |
T (°C) |
Acetone concentration (ppm) |
Response |
Reference |
Suparat Singkammo et al. |
Ni-doped SnO2 composite film |
350 |
200 |
54.2 |
3 |
S. B. Patil et al. |
Co-doped SnO2 thin films |
270 |
60 |
32 |
9 |
M. Punginsang et al. |
Co-doped SnO2 thin films |
250 |
20 |
36.9 |
10 |
R. K. Mishra et al. |
SnO2 nanoparticles |
250 |
10 |
42 |
11 |
W. X. Jin et al. |
SnO2 nanoflowers |
260 |
25 |
40 |
12 |
S. Wei et al. |
ZnO hollow nanofibers |
220 |
1 |
7.1 |
13 |
D. An et al. |
ZnO nanomaterials |
220 |
100 |
6.0 |
14 |
C. Peng et al. |
ZnO hollow nanofibers |
300 |
100 |
18.6 |
15 |
N. H. Al-Hardan et al. |
Cr-doped ZnO films |
400 |
500 |
90 |
16 |
D. Chen et al. |
WO3 nanoparticle |
300 |
2 |
2 |
17 |
S. Kim et al. |
WO3 with both Pd and Au |
300 |
200 |
152.4 |
19 |
L. Wang et al. |
Au-doped NiO hybrid structure |
240 |
20 |
7.6 |
20 |
C. Wang et al. |
W-doped NiO films |
250 |
100 |
198.1 |
21 |
Hao Shan et al. |
La-doped α-Fe2O3 nanomaterials |
240 |
50 |
26 |
22 |
Chang Su et al. |
Sm-doped α-Fe2O3 nanomaterials |
240 |
0.5 |
2.3 |
23 |
Z. Zhang et al. |
Co3O4 nanosheets |
150 |
10 |
1.7 |
24 |
M. Epifani et al. |
TiO2 nanocrystals |
400 |
100 |
1.2 |
26 |
B. Bhowmik et al. |
TiO2 nanotubes |
27 |
10 |
1.136 |
27 |
H. Bian et al. |
TiO2 nanorods |
500 |
10 |
9 |
28 |
C. Wang et al. |
CuO–ZnO nanoparticles |
340 |
10 |
3.7 |
29 |
X. Chi et al. |
ZnO–In2O3 composite nanotubes |
280 |
60 |
43.2 |
30 |
Z. L. Wu et al. |
NdFeO3 |
120 |
50 |
300 |
47 |
T. Chen et al. |
SmFeO3 |
250 |
380 |
2.6 |
48 |
X. Liu et al. |
SmFe0.9Mg0.1O3 |
260 |
300 |
353 |
49 |
X. Liu et al. |
LaFeO3 |
400 |
80 |
204 |
50 |
L. Zhang et al. |
La0.68Pb0.32FeO3 |
200 |
50 |
7 |
51 |
S. Zhang et al. |
In2O3 nanospheres |
350 |
10 |
53.08 |
65 |
S. Park et al. |
In2O3–TiO2 |
250 |
1 |
10 |
66 |
F. Chen et al. |
In2O3 |
250 |
50 |
12 |
67 |
W. Liu et al. |
Pt–In2O3 |
180 |
10 |
15.1 |
68 |
Y. Che et al. |
In2O3 |
200 |
100 |
37.9 |
69 |
Z. Song et al. |
Pt–In2O3 |
300 |
10 |
113 |
70 |
In this work, mesoscopic gyrus-like indium oxide with two-dimensional porous nanowalls synthesized from a high-molecular-weight di-block copolymer (PEO-b-PS) induced the In2O3 simple. Due to the support from the rigidity of the PS segments during the process of synthesis, the mesoscopic structure can be well obtained after ordered annealing in the air. This results in the mesoscopic gyrus-like nano-In2O3 with large specific area structure. Mesoscopic gyrus-like In2O3 materials have high porosity and unique crystal structures, and have excellent sensing properties to low-concentration acetone, such as fast response and recovery time, detection limit of sub-ppb and good selectivity in different gases. This excellent performance makes possible the use of intelligent gas sensors based on this In2O3 structure, which can be used in many fields, especially the non-invasive diagnosis of diabetes.
2. Materials and methods
2.1. Synthesis of mesoscopic grooved indium oxide
The laboratory-prepared amphiphilic block copolymer PEO112-b-PS165 synthesized according to an existing related research report64 was dissolved in 4.5 mL THF, and then a solution can be obtained. And then, 0.3 g of indium trichloride was dissolved in 3 mL ethanol. The two solutions were then mixed and stirred for half an hour to form a transparent and colorless solution. Then the solution was poured into a watch glass, the solvent was placed at room temperature for 2 hours (ambient humidity was controlled to <40% in order to prevent the InCl3 hydrolysis reaction with the water in the air), and then heated continuously at 60 °C for 5 hours and at 100 °C for 12 hours. Then the translucent film in a glass container was calcined in a muffle furnace at 400 °C with appropriate amount of CaO2 for 30 minutes at a rate of 4 °C min−1. Finally, the rolled film was ground into a yellow uniform powder.
2.2. Synthesis of mesoscopic grooved In2O3 nanocrystals
Fig. 1 illustrates the synthesis of indium oxide, firstly with the mixed solution including PEO112-b-PS165 di-block copolymer, ethanol, InCl3, and THF. With the solvent (mainly THF) at an ambient temperature of about 25 °C, the dissolved PEO-b-PS copolymer then gradually aggregated into columnar micelles with the PS segment as the gyrus because of the hydrophilic and hydrophobic end-to-end arrangement. Simultaneously part of the hydrolyzed hydrophilic inorganic indium interacted with the end of PEO by weak coordination bonds and hydrogen bonds. With the THF in the solution evaporating, a uniform and transparent rolled film formation was observed in the watch glass. Finally, the organic–inorganic hybrid membrane attached on the watch plate was prepared at 400 °C for 30 min. Calcium oxide was used to promote the decomposition of PEO-b-PS organics, the mesostructure being protected by the rapid release of oxygen. A series of mesoscopic gyrus-like In2O3-x-y-z nanocrystalline materials were synthesized, where x, y, z are related to the proportion by weight of PEO-b-PS polymer and InCl3, the annealing temperature and the time, respectively. Fig. 1 illustrates the induced assembly process for the mesoscopic gyrus-like In2O3 starting from the solution with the mixture containing PEO-b-PS di-block copolymer etc.
|
| Fig. 1 Illustration of the synthesis of mesoscopic gyrus-like In2O3. | |
A certain amount of indium oxide product synthesized by induction was mixed with an appropriate amount of deionized water, and then the mixture was loaded on an Al2O3 ceramic tube with two electrodes at one end in the form of a thick film. The ceramic tube was approximately 10 mm long, with an outer diameter of approximately 8 mm and an inner diameter of approximately 5 mm (Fig. 2). To improve the repeatability and stability, the gas sensor should be calcined at 200 °C for 3 h. The gas sensing properties of the nanocrystalline material were measured in the temperature range of 100–200 °C. The resistance of the sensor was measured in the air and guest gas (test), dry air being used as the carrier gas. The sensitivity of the thick-film sensor to the test gas is defined as S = Ra/Rg, where Ra is the resistance in air and Rg is the resistance in the test gas.
|
| Fig. 2 Schematic of the thick-film sensor. | |
3. Results and discussion
3.1. The X-ray diffraction (XRD) and the scanning electron microscope (SEM)
Wide angle X-ray diffraction (XRD) measurements showed that the In2O3-400-0.5 sample obtained after calcination of the prepared PEO-b-PS/In2O3 showed excellent resolved diffraction peaks in the 20–80° range (Fig. 3), consistent with the crystal-centered cubic phase of In2O3 (JCPDS no. 06-0416), which has no other diffraction peaks. Also, no other crystalline impurities were detected in the XRD pattern, indicating that In2O3 was purely crystalline. According to scanning electron microscopy (SEM), mesoscopic outer In2O3 indium oxide materials are observed, with an orderly walnut shape of the outer structure. With the change of calcination temperature, the nano structure of the samples shaped to be layer and block through carefully observation. According to the SEM images, the outer gap diameter is estimated at about 40 nm (Fig. 4).
|
| Fig. 3 The X-ray diffraction patterns of In2O3 annealed at different temperatures. | |
|
| Fig. 4 SEM images of mesoscopic gyrus-like In2O3 annealed at 400 °C for 30 min. | |
In order to investigate the crystallization behavior of In2O3 gyrus walls during the annealing process, non-PEO-b-PS-In2O3 hybrid nanocrystalline material was prepared and calcined at 400 °C and 450 °C for 0.5 h in air with a low-humidity environment. The results show that increasing of the annealing temperature at 400 °C can make In2O3 nanograins (without PEO-b-PS) grow large into nanosheets which have larger size about (400 nm × 300 nm), larger thickness (20–25 nm) and higher crystallinity (Fig. 5a). During this heating-up annealing process, the two-dimensional lamella layer morphology remains intact. By comparison, with the calcination temperature increasing from 400 °C to 450 °C, the nano-lamella layer In2O3 rapidly disappeared and discrete rhomboid octahedral particles with diameters of 500 nm were formed (Fig. 5b). This means that a calcination temperature as high as 450 °C can cause a significant change in the structure and morphology of gyrus indium oxide, and this is a typical thermodynamic transformation reaction process. And a further extension of the annealing time to 30 min at 450 °C resulted in the formation of In2O3 discrete particles with the shape of unique octahedra, which also is a typical stable morphology for In2O3 nanocrystals (Fig. 5a and b). Besides, the In2O3 particles' inhomogeneity of size was mainly because of the inhomogeneous mass transport between the conversion reactions from nanosheets to lamella layer and octahedral particles (Fig. 5). The XRD patterns of these samples all calcined at 400 °C with different times also confirm the morphological transformation phenomenon (Fig. 3). With the annealing temperature increasing, the diffraction intensity of these samples is gradually increased, indicating that the crystallinity of In2O3 is enhanced.
|
| Fig. 5 SEM images of In2O3 precursor (without PEO-b-PS) annealed at (a) 400 °C for 30 min and (b) 450 °C for 30 min. | |
The results above indicate that the copolymer (PEO-b-PS) strongly interacts with indium species (In3+) during the assembly process, which reduces the condensation and hydrolysis rates of indium species throughout this synthesis process. Even its presence reduces the indium species' crystallization rate.
3.2. Gas sensing properties of gyrus-like In2O3 crystal materials
In2O3 has an ordered mesoscopic gyrus-like structure. Because of the low resistivity (high conductivity) of In2O3, it has great advantages in high-performance gas sensing (chemical) for its (gyrus structure) high surface area. This not only provides large numbers of O vacancies for the adsorption sites of the sensing gas, but also facilitates the diffusion of guest gas molecules in the surface structure. Besides, due to the charge carriers' fast transport between the surface of gyrus-like structure and the bulk, the prepared In2O3 material can provide excellent response/recovery as a chemical gas sensor.
The sensing response of the gyrus-like In2O3 sensing film to acetone in the concentration range of 0.5–5 ppm was measured at 150 °C (the content of acetone in diabetic exhaled breath). Based on the definition of S = Ra/Rg, the responses for 0.5, 1, 2, and 5 ppm acetone were calculated to be 1.73, 2.67, 3.12 and 3.75, respectively. Limit of detection (LOD) of exhaled breath for the thick-film sensor is below 0.5 ppm for the detection of acetone, which set the threshold for acetone at greater than 0.8 ppm. In addition, the experimental results show that there is a good concentration saturation relationship between the sensing response (S = Ra/Rg) and the acetone concentration.
When the gas test box was removed, the exposure of the sensor is from acetone vapor to pure air, the acetone gas molecules immediately being desorbed from the indium trioxide surface and releasing the electrons pre-trapped on the surface. The resistance of the gyrus-like In2O3 thick-film sensor can almost return to the original value, indicating that the gas sensor has good reversibility (Fig. 6b). The response–recovery time of the thick-film sensor is also very fast. Taking the gyrus-like In2O3 sensor with 1 ppm acetone as an example: the response time is 20 seconds and the recovery time is 16 seconds. Compared to previous reports of acetone sensors based on different In2O3 nanostructures, this work's sensors showed better overall sensing performance, such as having a much lower operating temperature (150 °C) which is more amenable for fabricating flexible devices, and also higher sensitivity and much lower LOD, which are because of the following factors. Firstly, the In2O3 nanocrystalline material has a uniform nano-gyrus structure (about 40 nm) and the meso-grooved In2O3 materials not only facilitate the diffusion of guest gas molecules, but also can provide a large number of activation sites for the adsorption and desorption of acetone gas molecules. Besides, the crystalline particles in the mesoscopic In2O3 nanocrystalline structure provide fast transport of charge carriers (electrons) between the sensing film surface and the bulk. So the open mesoscopic gyrus-like structure and high crystallinity lead to excellent low concentration acetone sensing performance.
|
| Fig. 6 (a) The response of In2O3 nanocrystalline thick-film sensor to 100 ppm acetone at different operating temperatures. (b) The response and recovery curves of the gyrus-like In2O3 nanocrystalline sensor to acetone with different concentrations (0.5–5 ppm) at 150 °C. (c) The response (Ra/Rg) of the sensor vs. different acetone concentrations. (d) The selectivity of the In2O3 sensor to different guest gases (10 ppm) at 150 °C. | |
Gas selectivity is an important parameter of gas sensors, especially in the complex environment of human exhaled breath. In this study, acetone, carbon monoxide, ethanol, ammonia, formaldehyde, and other typical gas molecules were chosen as interference and mixed gases. As shown in Fig. 6d, the response to acetone of the sensor was mainly 5 times higher than that to 5 other selected interfering gases. The phenomenon of the excellent selectivity can be explained as follows: as a typical reducibility gas, the adsorbed oxygen with different valence states on the surface of In2O3 is substituted by acetone, which has a stronger ability to capture electrons of n-type In2O3 semiconductor than other gases.
The mechanism of a chemoreceptive gas sensor at suitable operating temperature is the conversion (resistance becomes larger and smaller) of electrical resistance between the surface reactions of the gas sensing materials. In2O3 is a typical n-type semiconductor. When the sensor was exposed to the air, the oxygen in the air can adsorb on the surface of In2O3 to form ionic oxygen species (O−, O2−) by capturing electrons from the conduction band of In2O3. Reducing/oxidizing gases can change the surface carrier concentration by capturing electrons from or releasing electrons to the conduction band of In2O3, acting as electron-donating groups. It is obvious that the amount of adsorbed oxygen species plays an indispensable role in the performance of the sensor. As the operating temperature increases, the In2O3-based sensors exhibit different sensitivity to acetone vapor at >150 °C, which may be due to the small coverage of adsorbed oxygen as well as a small change in resistivity below the LOD.
Therefore, when the gas sensor is exposed to acetone gas, the resistance of the sensor increases sharply. By contrast, the oxygen species may oxidize the interfering gas molecules, and such oxygen species (O−, O2−) are expended by the interfering gas molecules, and the electrons captured by oxygen are returned to In2O3 during the oxidation process. Consequently, setting the same gas sensor exposed to one kind of interfering gas, a response in the negative direction (decrease in resistance value) can be obtained. Under this sensing mechanism, it is obvious that all the typical interfering gases have a limited effect on the detection of acetone gas by the In2O3 nanocrystalline sensor. A possible mechanism of In2O3 and the sensing gas reaction process is shown in Fig. 7.
|
| Fig. 7 Schematic illustration of the acetone sensing mechanism of the sensor based on gyrus-like In2O3 in air and target gas–air mixture. | |
4. Conclusion
In summary, a di-block copolymer-induced method has been developed for the synthesis of gyrus-like indium oxides, which used high-molecular-weight di-block copolymer PEO-b-PS as a revulsive, and the indium source is indium chloride. THF/ethanol was used as the solvent. By the support of PS segments during the reaction, ordered gyrus-like In2O3 was obtained with a crystalline nanostructure of about 40 nm with high surface area. The obtained gyrus-like In2O3 nanocrystalline material was fabricated into thick-film sensors which can work at a relatively low temperature of about 150 °C. Also, the thick-film sensor exhibits an excellent sensing performance with a fast response–recovery time. And the LOD of 0.5 ppm is perfect for use as a diabetic exhaled gas (healthy range is 0.3–0.8 ppm) sensor, and shows very fine selectivity, which may be due to the high porosity of the gyrus-like In2O3 and the unique nanocrystalline framework. In conclusion, such excellent performance of the material in this work shows promise for fabricating In2O3-based sensors for application in non-invasive diagnosis of diabetes mellitus and preliminary screening. Furthermore, the nanocrystalline gyrus-like In2O3 with special structure can be expected to be used in many other applications, such as lithium storage, photocatalysis and so on. It has an important practical significance.
Conflicts of interest
There are no conflicts to declare.
Acknowledgements
This work was supported by Shandong Natural Science Foundation (no. ZR2019BEM036) and Shandong Jianzhu University Doctor’s Foundation (X19009Z).
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