Indium tin oxide

Indium tin oxide
Physical properties
Melting point 1800–2200 K (1526–1926 °C) (2800–3500 °F)
Density 7120–7160 kg/m3 at 293 K
Color (in powder form) Pale yellow to greenish yellow, depending on SnO2 concentration
Values vary with composition. SI units and STP are used except where noted.
absorption of glass and ITO glass
ITO grains on glass substrates with a few nano-particle impurities

Indium tin oxide (ITO) is a ternary composition of indium, tin and oxygen in varying proportions. Depending on the oxygen content, it can either be described as a ceramic or alloy. Indium tin oxide is typically encountered as an oxygen-saturated composition with a formulation of 74% In, 18% O2, and 8% Sn by weight. Oxygen-saturated compositions are so typical, that unsaturated compositions are termed oxygen-deficient ITO. It is transparent and colorless in thin layers, while in bulk form it is yellowish to grey. In the infrared region of the spectrum it acts as a metal-like mirror.

Indium tin oxide is one of the most widely used transparent conducting oxides because of its two main properties: its electrical conductivity and optical transparency, as well as the ease with which it can be deposited as a thin film. As with all transparent conducting films, a compromise must be made between conductivity and transparency, since increasing the thickness and increasing the concentration of charge carriers increases the material's conductivity, but decreases its transparency.

Thin films of indium tin oxide are most commonly deposited on surfaces by physical vapor deposition. Often used is electron beam evaporation, or a range of sputter deposition techniques.

Common uses

Indium tin oxide (ITO) is an optoelectronic material that is applied widely in both research and industry. ITO can be used for many applications, such as flat-panel displays, smart windows, polymer-based electronics, thin film photovoltaics, and architectural windows. Moreover, ITO thin films for glass substrates can be helpful for glass windows to conserve energy.[1]

ITO green tapes are utilized for the production of lamps that are electroluminescent, functional, and fully flexible.[2] Also, ITO thin films are used primarily to serve as coatings that are anti-reflective and for liquid crystal displays (LCDs) and electroluminescence, where the thin films are used as conducting, transparent electrodes.[3]

ITO is often used to make transparent conductive coatings for displays such as liquid crystal displays, flat panel displays, plasma displays, touch panels, and electronic ink applications. Thin films of ITO are also used in organic light-emitting diodes, solar cells, antistatic coatings and EMI shieldings. In organic light-emitting diodes, ITO is used as the anode (hole injection layer).

ITO films deposited on windshields are used for defrosting aircraft windshields. The heat is generated by applying voltage across the film.

Thin film interference caused by ITO defrosting coating on an Airbus cockpit window. The film thickness is intentionally non-uniform to provide even heating at different distances from the electrodes.

ITO is also used for various optical coatings, most notably infrared-reflecting coatings (hot mirrors) for automotive, and sodium vapor lamp glasses. Other uses include gas sensors, antireflection coatings, electrowetting on dielectrics, and Bragg reflectors for VCSEL lasers. ITO is also used as the IR reflector for low-e window panes. ITO was also used as a sensor coating in the later Kodak DCS cameras, starting with the Kodak DCS 520, as a means of increasing blue channel response.[4]

ITO thin film strain gauges can operate at temperatures up to 1400 °C and can be used in harsh environments, such as gas turbines, jet engines, and rocket engines.[5]

Material and spectral properties

ITO is a heavily-doped n-type semiconductor with a large bandgap of around 4 eV.[6] Because of the bandgap, it is mostly transparent in the visible part of the spectrum and its extinction coefficient, k, in this wavelength range is zero. In the ultraviolet (UV), it is opaque, so that k is non zero in the UV spectral range, because of band-to-band absorption (a UV photon can excite an electron from the valence band to the conduction band). It is also opaque in the near infrared (NIR) and infrared (IR), because of free carrier absorption (an infrared photon can excite an electron from near the bottom of the conduction band to higher within the conduction band). In this wavelength range k is non-zero, and reaches its maximum value in the IR regime, similar to the behavior of k for metals.

ITO has attractive properties including high level of transmittance in the visible region as well as electrical conductivity that is unique. This is mainly due to ITO’s highly degenerate behavior as an n-type semiconductor with a large band gap of around 3.5 to 4.3 eV.[3]

Alternative synthesis methods and alternative materials

Because of high cost and limited supply of indium, the fragility and lack of flexibility of ITO layers, and the costly layer deposition requiring vacuum, alternative methods of preparing ITO and alternative materials are being investigated.[7]

Alternative materials

Doped compounds

Alternative materials can also be used. Doped binary compounds such as aluminum-doped zinc-oxide (AZO) and indium-doped cadmium-oxide have been proposed as alternative materials. Other, inorganic alternatives include aluminum, gallium or indiumdoped zinc oxide (AZO, GZO or IZO).

Carbon nanotubes

Carbon nanotube conductive coatings are a prospective replacement.[8][9]

Graphene

As another carbon-based alternative, films of graphene are flexible and have been shown to allow 90% transparency with a lower electrical resistance than standard ITO.[10] Thin metal films are also seen as a potential replacement material. A hybrid material alternative currently being tested is an electrode made of silver nanowires and covered with graphene. The advantages to such materials include maintaining transparency while simultaneously being electrically conductive and flexible.[11]

Conductive polymers

Inherently conductive polymers (ICPs) are also being developed for some ITO applications.[12][13] Typically the conductivity is lower for conducting polymers, such as polyaniline and PEDOT:PSS, than inorganic materials, but they are more flexible, less expensive and more environmentally friendly in processing and manufacture.

Amorphous indium–zinc oxide

In order to reduce indium content, decrease processing difficulty, and improve electrical homogeneity, amorphous transparent conducting oxides have been developed. One such material, amorphous indium-zinc-oxide maintains short-range order even though crystallization is disrupted by the difference in the ratio of oxygen to metal atoms between In2O3 and ZnO. Indium-zinc-oxide has some comparable properties to ITO.[14] The amorphous structure remains stable even up to 500 °C, which allows for important processing steps common in organic solar cells.[7] The improvement in homogeneity significantly enhances the usability of the material in the case of organic solar cells. Areas of poor electrode performance in organic solar cells render a percentage of the cell’s area unusable.[15]

Process of the AgNP into the polymer substrate

Silver nanoparticle–ITO hybrid

ITO has been popularly used as a high-quality flexible substrate to produce flexible electronics.[16] However, this substrate's flexibility decreases as its conductivity improves. Previous research have indicated that the mechanical properties of ITO can be improved through increasing the degree of crystallinity.[17] Doping with silver (Ag) can improve this property, but results in a loss of transparency.[18] An improved method that embeds Ag nanoparticles (AgNPs) instead of homogeneously to create a hybrid ITO has proven to be effective in compensating for the decrease in transparency. The hybrid ITO consists of domains in one orientation grown on the AgNPs and a matrix of the other orientation. The domains are stronger than the matrix and function as barriers to crack propagation, significantly increasing the flexibility. The change in resistivity with increased bending significantly decreases in the hybrid ITO compared with homogenous ITO.[19]

Alternative synthesis methods

Tape casting process

ITO is typically deposited through expensive and energy-intensive processes that deal with physical vapor deposition (PVD). Such processes include sputtering, which results in the formation of brittle layers. An alternative process that uses a particle-based technique, is known as the tape casting process. Because it is a particle-based technique, the ITO nano-particles are dispersed first, then placed in organic solvents for stability. Benzyl phthalate plasticizer and polyvinyl butyral binder have been shown to be helpful in preparing nanoparticle slurries. Once the tape casting process has been carried out, the characterization of the green ITO tapes showed that optimal transmission went up to about 75%, with a lower bound on the electrical resistance of 2 Ω·cm.[2]

Laser sintering

Using ITO nanoparticles imposes a limit on the choice of substrate, owing to the high temperature required for sintering. As an alternative starting material, In-Sn alloy nanoparticles allow for a more diverse range of possible substrates.[20] A continuous conductive In-Sn alloy film is formed firstly, followed by oxidation to bring transparency. This two step process involves thermal annealing, which requires special atmosphere control and increased processing time. Because metal nanoparticles can be converted easily into a conductive metal film under the treatment of laser, laser sintering is applied to achieve products' homogeneous morphology. Laser sintering is also easy and less costly to use since it can be performed in air.[21]

Sol-gel deposition

A promising method, from a cost perspective, is to eliminate the need for vacuum deposition equipment. This can be accomplished using a sol-gel method,[22] which several groups are working on.[23][24]

Ambient gas conditions

For example, using conventional methods but varying the ambient gas conditions to improve the optoelectronic properties [25] as, for example, oxygen plays a major role in the properties of ITO.[26]

Chemical Shaving for Very Thin Films

There has been numerical modeling of plasmonic metallic nanostructures have shown great potential as a method of light management in thin-film nanodisc-patterned hydrogenated amorphous silicon (a-Si:H) solar photovoltaic (PV) cells. A problem that arises for plasmonic-enhanced PV devices is the requirement for ‘ultra-thin’ transparent conducting oxides (TCOs) with high transmittance and low enough resistivity to be used as device top contacts/electrodes. Unfortunately, most work on TCOs is on relatively thick layers and the few reported cases of thin TCO showed a marked decrease in conductivity. To overcome this it is possible to first grow a thick layer and then chemically shave it down to obtain a thin layer that is whole and highly conductive.[27]

Constraints and trade-offs

The main concern about ITO is the cost. ITO can be priced several times more highly than aluminium zinc oxide (AZO). AZO is a common choice of transparent conducting oxide (TCO) because of cost and relatively good optical transmission performance in the solar spectrum. However, ITO does consistently defeat AZO in almost every performance category including chemical resistance to moisture. ITO is not affected by moisture and it can survive in a copper indium gallium selenide solar cell cell for 25–30 years on a rooftop. While the sputtering target or evaporative material that is used to deposit the ITO is significantly more costly than AZO, the amount of material placed on each cell is quite small. Therefore the cost penalty per cell is quite small too.

Benefits

Surface morphology changes in Al:ZnO and i-/Al:ZnO upon dump heat (DH) exposure (optical interferometry)[28]

The primary advantage of ITO compared to AZO as a transparent conductor for LCDs is that ITO can be precisely etched into fine patterns.[29] AZO cannot be etched as precisely: It is so sensitive to acid that it tends to get over-etched by an acid treatment.[29]

Another benefit of ITO compared to AZO is that if moisture does penetrate,ITO will degrade less than AZO.[28]

The role of ITO glass as a cell culture substrate can be extended easily, which opens up new opportunities for studies on growing cells involving electron microscopy and correlative light.[30]

Research examples

ITO can be used in nanotechnology to provide a path to a new generation of solar cells. Solar cells made with these devices have the potential to provide low-cost, ultra-lightweight, and flexible cells with a wide range of applications. Because of the nanoscale dimensions of the nanorods, quantum-size effects influence their optical properties. By tailoring the size of the rods, they can be made to absorb light within a specific narrow band of colors. By stacking several cells with different sized rods, a broad range of wavelengths across the solar spectrum can be collected and converted to energy. Moreover, the nanoscale volume of the rods leads to a significant reduction in the amount of semiconductor material needed compared to a conventional cell.[31][32]

Health and safety

Indium tin oxide is harmful in that it may cause mild irritation in the respiratory tracts and should not be inhaled. If exposure is long-term, symptoms may become chronic and result in benign pneumoconiosis. Studies with animals indicate that indium tin oxide is toxic when ingested, along with negative effects on the kidney, lung, and heart.[33]

During the process of mining, production and reclamation, workers are potentially exposed to indium, especially in countries such as China, Japan, the Republic of Korea, and Canada[34] and face the possibility of pulmonary alveolar proteinosis, pulmonary fibrosis, emphysema, and granulomas. Workers in the US, China, and Japan have been diagnosed with cholesterol clefts under indium exposure.[35] Silver nanoparticles existed in improved ITOs have been found in vitro to penetrate through both intact and breached skin into the epidermal layer. Un-sintered ITOs are suspected of induce T-cell-mediated sensitization: on a intradermal exposure study, a concentrarion of 5% uITO resulted in lymphocyte proliferation in mice including the number increase of cells through a 10-day period.[36]

A new occupational problem called indium lung disease was developed through contact with indium-containing dusts. The first patient is a worker associated with wet surface grinding of ITO who suffered from interstitial pneumonia: his lung was filled with ITO related particles.[37] These particles can also induce cytokine production and macrophage dysfunction. Sintered ITOs particles alone can cause phagocytic dysfunction but not cytokine release in macrophage cells; however, they can intrigue a pro-inflammatory cytokine response in pulmonary epithelial cells. Unlike uITO, they can also bring endotoxin to workers handling the wet process if in contact with endotoxin-containing liquids. This can be attributed to the fact that sITOs have larger diameter and smaller surface area, and that this change after the sintering process can cause cytotoxicity.[38]

Recycling

Process of indium-tin-oxide (ITO) etching wastewater treatment

The etching water used in the process of sintering ITO can only be used for a limited numbers of times before disposed. After degradation, the waste water should still contain valuable metals such as In, Cu as secondary resource as well as Mo, Cu, Al, Sn and In which can pose health a hazard to human beings.[39][40][41][42][43][44][45][46][47] [Next few sentences sound like an advertisement for a not-yet-accepted method] Among all the current methods of recycling such waste-water, one outstandingly uses non-toxic chemicals and applies scrubbing, stripping, liquid-liquid extraction and precipitation. The final product will meet the standard of the World Health Organization and be available for second-time uses. This method follows the green chemistry standard and allows for massive commercial reuse while maintaining the purity of the recycled In, Mo, Sn and Cu nanopowder.[48]

See also

References

  1. Kim, H.; Gilmore, C.; Pique, A.; Horwitz, J.; Mattoussi, H.; Murata, H.; Kafafi, Z.; Chrisey, D. Electrical, Optical, and Structural Properties of Indium–Tin–Oxide Thin Films for Organic Light-Emitting Devices. Journal of Applied Physics [Online] 86,11.
  2. 1 2 Straue, N.; Rauscher, M.; Dressler, M.; Roosen, A.; Moreno, R.; Tape Casting of ITO Green Tapes for Flexible Electroluminescent Lamps. Journal of the American Ceramic Society [Online] 2012, 95, 684-689.
  3. 1 2 Du, J.; Chen, X.; Liu, C.; Ni, J.; Hou, G.; Zhao, Y.; Zhang, X. Highly Transparent and Conductive Indium Tin Oxide Thin Films for Solar Cells Grown by Reactive Thermal Evaporation at Low Temperature. Applied Physics A: Materials Science & Processing [Online] 2014, 117, 2.
  4. KODAK PROFESSIONAL: Technical Information Bulletin: Increasing the Blue Channel Response
  5. Qing Luo. "Indium tin oxide thin film strain gages for use at elevated temperatures". Retrieved 2010-03-18.
  6. Kim H. Gilmore C. M. Piqué A. Horwitz J. S.Mattoussi H. Murata H. Kafafi Z. H. Chrisey D. B. "Electrical, optical, and structural properties of indium–tin–oxide thin films for organic light-emitting devices". Journal of Applied Physics.1 December 1999. 86. 11. pp. 645. 10.1063/1.371708 http://scitation.aip.org/content/aip/journal/jap/86/11/10.1063/1.371708
  7. 1 2 Fortunato, E.; D. Ginley; H. Hosono; D.C. Paine (March 2007). "Transparent Conducting Oxides for Photovoltaics". MRS Bulletin. 32: 242–247. doi:10.1557/mrs2007.29.
  8. "Researchers find replacement for rare material indium tin oxide" (online). R&D Magazine. Advantage Business Media. 11 April 2011. Retrieved 11 April 2011.
  9. Kyrylyuk, Andriy V.; Hermant, Marie Claire; Schilling, Tanja; Klumperman, Bert; Koning, Cor E.; van der Schoot, Paul (10 April 2011), "Controlling electrical percolation in multicomponent carbon nanotube dispersions", Nature Nanotechnology, Nature Publishing Group, Advance Online Publication, retrieved 11 April 2010
  10. "Graphene Finally Goes Big". Science Now. AAAS. June 20, 2010. Retrieved 17 March 2011.
  11. Chen, Ruiyi; Suprem R. Das; Changwook Jeong; Mohammad Ryyan Khan; David B. Janes; Muhammad A. Alam (April 2013). "Co-Percolating Graphene-Wrapped Silver Nanowire Network for High Performance, Highly Stable, Transparent Conducting Electrodes". Advanced Functional Materials. doi:10.1002/adfm.201300124.
  12. Xia, Yijie; Sun, Kuan; Ouyang, Jianyong (8 May 2012). "Solution-Processed Metallic Conducting Polymer Films as Transparent Electrode of Optoelectronic Devices". Advanced Materials. 24 (18): 2436–2440. doi:10.1002/adma.201104795.
  13. Saghaei, Jaber; Fallahzadeh, Ali; Saghaei, Tayebeh (September 2015). "ITO-free organic solar cells using highly conductive phenol-treated PEDOT:PSS anodes". Organic Electronics. 24: 188–194. doi:10.1016/j.orgel.2015.06.002.
  14. Ito, N., Sato, Y., Song, P. K., Kaijio, A., Inoue, K., & Shigesato, Y. (2006). Electrical and optical properties of amorphous indium zinc oxide films. Thin Solid Films, 496(1), 99-103.
  15. Irwin, Michael D.; Liu, Jun; Leever, Benjamin J.; Servaites, Jonathan D.; Hersam, Mark C.; Durstock, Michael F.; Marks, Tobin J. (16 February 2010). "Consequences of Anode Interfacial Layer Deletion. HCl-Treated ITO in P3HT:PCBM-Based Bulk-Heterojunction Organic Photovoltaic Devices". Langmuir. 26 (4): 2584–2591. doi:10.1021/la902879h.
  16. Z. Suo, J. Vlassak, and S. Wagner, China Particuol. 3(6), 321 (2005). | 2) N. S. Lu, C. Lu, S. X. Yang, and J. Rogers, Adv. Funct. Mater. 22(19),4044 (2012).
  17. E.-H. Kim, C.-W. Yang, and J.-W. Park, J. Appl. Phys. 109, 043511 (2011).
  18. C. W. Yang and J. W. Park, Surf. Coat. Technol. 204(16-17), 2761 (2010).
  19. Triambulo, R.E.; Kim, J.; Na, M.; Chang, H.; Park, J. Highly Flexible, Hybrid-Structured Indium Tin Oxides for Transparent Electrodes on Polymer Substrates. Applied Physics Letters [Online] 2013, 102, 24, p241913
  20. Ohsawa, M., Hayashi, S., 2011. J.P. Patent 2011090969. Ohsawa, M., Sakio, S., Saito, K., 2011. Development of nanoparticle ink for ITO transparent conductive films. J. Jpn. Inst. Electron. Pack. 14, 453–459.
  21. Qin, G.; Fan, L.; Watanabe, A. Formation of Indium Tin Oxide Film by Wet Process Using Laser Sintering. Journal of Materials Processing Technology [Online] 2016, 227, 16-23, 8p.
  22. Marikkannan, M., Vishnukanthan, V., Vijayshankar, A., Mayandi, J. and Pearce, J. M., A novel synthesis of tin oxide thin films by the sol-gel process for optoelectronic applications.AIP Advances, 5, 027122 (2015).
  23. Alam, M. J., & Cameron, D. C. (2000). Optical and electrical properties of transparent conductive ITO thin films deposited by sol–gel process. Thin solid films, 377, 455-459.
  24. Stoica, T. F., Teodorescu, V. S., Blanchin, M. G., Stoica, T. A., Gartner, M., Losurdo, M., & Zaharescu, M. (2003). Morphology, structure and optical properties of sol–gel ITO thin films. Materials Science and Engineering: B, 101(1), 222-226.
  25. Marikkannan, M. and Subramanian, M. and Mayandi, J. and Tanemura, M. and Vishnukanthan, V. and Pearce, J. M., Effect of ambient combinations of argon, oxygen, and hydrogen on the properties of DC magnetron sputtered indium tin oxide films, AIP Advances, 5, 017128 (2015).
  26. J. Gwamuri, M. Marikkannan, J. Mayandi, P. K. Bowen, J. M. Pearce. Influence of Oxygen Concentration on the Performance of Ultra-Thin RF Magnetron Sputter Deposited Indium Tin Oxide Films as a Top Electrode for Photovoltaic Devices. Materials, 9(1), 63 (2016). doi:10.3390/ma9010063
  27. Jephias Gwamuri, Ankit Vora, Jeyanthinath Mayandi, Durdu Ö. Güney, Paul L. Bergstrom, Joshua M. Pearce. A new method of preparing highly conductive ultra-thin indium tin oxide for plasmonic-enhanced thin film solar photovoltaic devices. Solar Energy Materials and Solar Cells 149,(2016): 250–257. doi: 10.1016/j.solmat.2016.01.028
  28. 1 2 "National Renewable Energy Laboratory" (PDF).
  29. 1 2 Handbook of Transparent Conductors, by David S. Ginley, p524, Google books link.
  30. Pluk, H.; Stokes, D.; Lich, B.; Wieringa, B.; Fransen, J. Advantages of Indium-Tin Oxide-Coated Glass Slides in Correlative Scanning Electron Microscopy Applications of Uncoated Cultured Cells. Journal of Microscopy [Online] 2009, 233, 3.
  31. National Nanotechnology Initiative. "Energy Conversion and Storage: New Materials and Processes for Energy Needs" (PDF). Archived from the original (PDF) on May 12, 2009.(dead link)
  32. "National Nanotechnology Initiative Research and Development Supporting the next Industrial Revolution, page 29" (PDF).
  33. Hosono, H.; Kurita, M.; Kawazoe, H. Excimer Laser Crystallization of Amorphous Indium-Tin-Oxide and Its Application to Fine Patterning. Japanese Journal of Applied Physics [Online] 37, 10.
  34. POLINARES (EU Policy on Natural Resources). 2012. Fact sheet: Indium. Available from: http://www.polinares.eu/docs/d21/polinares_wp2_annex2_factsheet5_v1_10.pdf [last accessed 20 Mar 2013]
  35. Cummings, K. J., Nakano, M., Omae, K., et al. 2012. Indium lung disease. Chest 141:1512–1521.
  36. Brock, K.; Anderson, E.; Lukomska, E.; Long, C.; Anderson, K.; Marshall, N.; Jean Meade, B. Immune Stimulation Following Dermal Exposure to Unsintered Indium Tin Oxide. Journal of Immunotoxicology [Online] 2014, 11, 268–272, 5p.
  37. Homma T., Ueno T., Sekizawa K., Tanaka A., Hirata M. Interstitial pneumonia developed in a worker dealing with particles containing indium-tin oxide. J Occup Health. 2003; 45(3): 137–9. PMID 14646287.
  38. Melissa, A.; Schwegler-Berry, D.; Park, J.; Fix, R.; Cummings, J.; Leonard, S. Sintered Indium-Tin Oxide Particles Induce Pro-Inflammatory Responses in Vitro, in Part through Inflammasome Activation. PloS ONE [Online] 2015, 10, 1–21, 21p.
  39. B. A. Fowler, H. Yamauchi, E. A. Conner and M. Akkerman, Scand. J. Work Environ. Health, 1993, 19(Suppl 1),101–103.
  40. H. Nogami, T. Shimoda, S. Shoji and S. Nishima, Nihon Kokyuki Gakkai Zasshi, 2008, 46, 60–64.
  41. T. Chonan, O. Taguchi and K. Omae, Eur. Respir. J., 2007, 29, 317–324.
  42. D. G. Barceloux and D. Barceloux, Clin. Toxicol., 1999, 37, 231–237.
  43. D. G. Barceloux and D. Barceloux, Clin. Toxicol., 1999, 37, 217–230.
  44. U. C. Gupta and S. C. Gupta, Commun. Soil Sci. Plant Anal., 1998, 29, 1491–1522.
  45. New Jersey Department of Health and Senior Services, hazardous substance factsheet., http://nj.gov/health/eoh/rtkweb/documents/fs/1025.pdf, Accessed 05/06/2015,2016.
  46. Lenntech, Health effects of tin, http://www.lenntech.com/periodic/elements/sn.htm, Accessed 12/12/2014, 2014.
  47. R. A. Yokel, in Encyclopedia of the Neurological Sciences, ed. M. J. Aminoff and R. B. Daroff, Academic Press, Oxford, 2nd edn, 2014, pp. 116–119.
  48. Swain, B.; Mishra, C.; Hong, S.; Cho, S. Treatment of Indium-tin-oxide Etching Wastewater and Recovery of In, Mo, Sn and Cu by Liquid–liquid Extraction and Wet Chemical Reduction: A Laboratory Scale Sustainable Commercial Green Process. Green Chemistry [Online] 2015, 17, 4418-4431.

External links

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