Your search keyword '"Kyongjun Kim"' showing total 20 results

1. SlaBins: Fisheye Depth Estimation using Slanted Bins on Road Environments.

Author

Jongsung Lee 0007, Gyeongsu Cho, Jeongin Park, Kyongjun Kim, Seongoh Lee, Jung-Hee Kim, Seong-Gyun Jeong, and Kyungdon Joo

Published

2023

2. A robust ionic liquid–polymer gate insulator for high-performance flexible thin film transistors

Author

Su Jeong Lee, Keon-Hee Lim, Jae Min Myoung, Kyongjun Kim, Jeeyoung Yoo, Youn Sang Kim, Jieun Ko, and Eungkyu Lee

Subjects

chemistry.chemical_classification, Materials science, Hydrogen bond, Ionic bonding, General Chemistry, Polymer, Capacitance, Flexible electronics, chemistry.chemical_compound, chemistry, Thin-film transistor, Ionic liquid, Materials Chemistry, Composite material, Layer (electronics)

Abstract

Herein, we propose an ionic liquid–polymer dielectric layer for flexible electronics reinforced by a chemical interaction between the polymer matrix (PVP) and the ionic liquid. Due to the robust structures of the cross-linked PVP matrix and hydrogen bonding between the ionic liquid and PVP, the ionic liquid–PVP (IL–PVP) layer exhibited a good mechanical strength when bending up to 1000 times and a stable thermal behaviour up to 300 °C. Furthermore, the IL–PVP dielectric layer showed a high capacitance value of ∼2 μF cm−2 and was operated well as a gate insulator for flexible ZnO thin film transistors with a linear field-effect mobility of ∼3.3 cm2 V−1 s−1 at a gate bias of 3 V.

Published

2015

3. Gate Capacitance-Dependent Field-Effect Mobility in Solution-Processed Oxide Semiconductor Thin-Film Transistors

Author

Si Yun Park, Eungkyu Lee, Jieun Ko, Youn Sang Kim, Keon-Hee Lim, Kyongjun Kim, and J.M. Myoung

Subjects

Materials science, business.industry, Transistor, Field effect, Hardware_PERFORMANCEANDRELIABILITY, Dielectric, Condensed Matter Physics, Nanocrystalline material, Electronic, Optical and Magnetic Materials, law.invention, Amorphous solid, Biomaterials, Gate oxide, law, Thin-film transistor, Electrical resistivity and conductivity, Hardware_INTEGRATEDCIRCUITS, Electrochemistry, Optoelectronics, business, Hardware_LOGICDESIGN

Abstract

Solution-processed oxide semiconductors (OSs) used as channel layer have been presented as a solution to the demand for flexible, cheap, and transparent thin-film transistors (TFTs). In order to produce high-performance and long-sustainable portable devices with the solution-processed OS TFTs, the low-operational voltage driving current is a key issue. Experimentally, increasing the gate-insulator capacitances by high-k dielectrics in the OS TFTs has significantly improved the field-effect mobility of the OS TFTs. But, methodical examinations of how the field-effect mobility depends on gate capacitance have not been presented yet. Here, a systematic analysis of the field-effect mobility on the gate capacitances in the solution-processed OS TFTs is presented, where the multiple-trapping-and-release and hopping percolation mechanism are used to describe the electrical conductivity of the nanocrystalline and amorphous OSs, respectively. An intuitive single-piece expression showing how the field-effect mobility depends on gate capacitance is developed based on the aforementioned mechanisms. The field-effect mobility, depending on the gate capacitances, of the fabricated ZnO and ZnSnO TFTs clearly follows the theoretical prediction. In addition, the way in which the gate insulator properties (e.g., gate capacitance or dielectric constant) affect the field-effect mobility maximum in the nanocrystalline ZnO and amorphous ZnSnO TFTs are investigated.

Published

2014

4. Solution-processed amorphous hafnium-lanthanum oxide gate insulator for oxide thin-film transistors

Author

Si Yun Park, Eungkyu Lee, Joohee Kim, Jieun Ko, Youn Sang Kim, Kyongjun Kim, and Keon-Hee Lim

Subjects

Materials science, business.industry, Gate dielectric, Time-dependent gate oxide breakdown, General Chemistry, Dielectric, Oxide thin-film transistor, Gate oxide, Materials Chemistry, Optoelectronics, Breakdown voltage, business, Leakage (electronics), High-κ dielectric

Abstract

Solution-processed high-K dielectrics for oxide thin-film transistors (TFTs) have been widely studied with the objective of achieving high performance and low-cost TFTs for next-generation displays. In this study, we introduce an amorphous hafnium-lanthanum oxide (HfLaOx) gate insulator with high electrical permittivity which was fabricated by the simple spin-coating method. In particular, the solution-processed HfLaOx dielectric layer, which was achieved by a mixture of two Hf and La metal hydroxide precursors, showed amorphous properties, a low leakage current and a high dielectric constant. The solution-processed HfLaOx dielectric layers showed a breakdown voltage as high as 5 MV cm−1 in strength and a dielectric constant above 22. Based on their implementation as a gate insulator, the solution-processed ZnO/HfLaOx TFTs showed good and stable performances during operation at a low voltage. A mobility of μ = 1.6 cm2 V−1 s−1, an on/off current ratio of 106, and a threshold voltage of 0.0015 V were obtained under a 5 V gate bias. Our results show the possibility of the solution-processed amorphous HfLaOx dielectric layer as a gate insulator for oxide TFTs. We believe that this amorphous HfLaOx dielectric has good potential for next-generation high-performance TFT devices.

Published

2014

5. UV-Visible Spectroscopic Analysis of Electrical Properties in Alkali Metal-Doped Amorphous Zinc Tin Oxide Thin-Film Transistors

Author

Youn Sang Kim, Seonjo Kim, Kyongjun Kim, Si Yun Park, Keon-Hee Lim, and Hyungjun Kim

Subjects

Materials science, Band gap, business.industry, Mechanical Engineering, Inorganic chemistry, Doping, Field effect, Alkali metal, Amorphous solid, Semiconductor, Mechanics of Materials, Thin-film transistor, Optoelectronics, General Materials Science, business, Burstein–Moss effect

Abstract

Solution-processed and alkali metals, such as Li and Na, are introduced in doped amorphous zinc tin oxide (ZTO) semiconductor TFTs, which show better electrical performance, such as improved field effect mobility, than intrinsic amorphous ZTO semiconductor TFTs. Furthermore, by using spectroscopic UV-visible analysis we propose a comprehensive technique for monitoring the improved electrical performance induced by alkali metal doping in terms of the change in optical properties. The change in the optical bandgap supported by the Burstein-Moss theory could successfully show a mobility increase that is related to interstitial doping of alkali metal in ZTO semiconductors.

Published

2013

6. Low-Temperature, Solution-Processed and Alkali Metal Doped ZnO for High-Performance Thin-Film Transistors

Author

Hong Koo Baik, Keon-Hee Lim, Moon Sung Kang, Si Yun Park, Jeong Ho Cho, J.M. Myoung, Tae Il Lee, Kyongjun Kim, Youn Sang Kim, and Beom Joon Kim

Subjects

Amorphous silicon, Materials science, Transistors, Electronic, Silicon, Metals, Alkali, business.industry, Mechanical Engineering, Doping, Inorganic chemistry, Temperature, chemistry.chemical_element, Solutions, chemistry.chemical_compound, Electron transfer, Semiconductor, chemistry, Mechanics of Materials, Thin-film transistor, Optoelectronics, General Materials Science, Chemical stability, Electronics, Zinc Oxide, business

Abstract

) and its dep-osition requires a high-cost vacuum process. More importantly, the poor transparency of silicon makes it unsuitable for trans-parent applications, and transparency is one of the key issues for future display technology. Consequently, in a search for alterna-tives for amorphous silicon, considerable interest has focused on metal oxide semiconductors, such as In, Ga, or Zn oxides, as these exhibit high optical transparencies, and have excel-lent electrical properties with high electron mobility, chemical stability, and solution processability. For example, ZnO-based semiconductors have been successfully incorporated into var-ious electronic devices, such as electron transfer layers for solar cells

Published

2012

7. Patterning of Flexible Transparent Thin-Film Transistors with Solution-Processed ZnO Using the Binary Solvent Mixture

Author

Kyongjun Kim, Youn Sang Kim, Jong-Baek Seon, Si Yun Park, Keon-Hee Lim, Kyusoon Shin, and Kookheon Char

Subjects

Materials science, business.industry, Band gap, Ripple, Transistor, Window (computing), Backlight, Condensed Matter Physics, Flexible electronics, Electronic, Optical and Magnetic Materials, law.invention, Biomaterials, law, Thin-film transistor, Electrochemistry, Transmittance, Optoelectronics, business

Abstract

As transparent displays become recog-nized as next-generation displays, the transparent thin-fi lm transistor (TTFT) is becoming an important device in the display industry. In addition, because the transparent device is causing a strong ripple effect through the whole industry, it has been spotlighted in response to changing markets and technological demands. For example, this technology can be applied to ultra-mobile PCs, smart windows, transparent tablets, and paper-thin displays. In particular, one anticipated application is the smart window. The smart window could transmit visual information onto the windshields of automobiles and airplanes. The use of transparent window displays has no limitations in space and visibility. Therefore, the transparent device has the potential to drive the future of the IT industry. From a technological standpoint, advances in trans-parent devices mean an increase in the transmittance in order to enhance the aperture ratio of device. Higher transmittance of the thin fi lm transistor (TFT) allows the effective use of back light and improves power consumption effi ciency. In order to achieve the TTFT, the development of transparent materials must be fi rst addressed. Of prime importance is zinc oxide (ZnO) with extensive applications in the industry. ZnO is a wide bandgap (

Published

2011

8. Compact Coarse Approach Mechanism for a Scanning Probe Microscope

Author

Junhong Kim, Duhwan Hwang, Yongho Seo, and Kyongjun Kim

Subjects

Materials science, business.industry, General Physics and Astronomy, Scanning capacitance microscopy, Temperature cycling, Piezoelectricity, Shear (sheet metal), Scanning probe microscopy, Optics, Spring (device), Composite material, business, Actuator, Vibrational analysis with scanning probe microscopy

Abstract

We report a compact design for a coarse approach mechanism, the so-called `walker', for a lowtemperature ultra-high-vacuum scanning probe microscope. We adapted the slip-stick principle with three actuators driven by the time sequential scheme suggested by Pan et al. The shear piezo-stack was replaced by three rectangular pieces of a piezoelectric (PZT) actuator to reduce the walker volume. Three slip-stick actuators were used rather than six actuators in the original design. By using polished sapphire and rough alumina plates, we implemented perfect sticking and a sliding interface. Our design minimizes usage of glue or epoxy, where attachment strength would be deteriorated by repeated temperature cycling. By using te on material, we reduced the frictional force of sliding parts. Without a metallic spring, elastic motion was provided by the te on material against the holding force. A moving velocity of 18 m/s and a step distance of 0.3 m were measured at room temperature.

Published

2008

9. Fast, exact, and non-destructive diagnoses of contact failures innano-scale semiconductor device using conductive AFM

Author

Yu-Sin Yang, Jeong-hoi Kim, ChaeHo Shin, Sang-Kil Lee, Woo-Seok Ko, Kyongjun Kim, Chung Sam Jun, and Youn Sang Kim

Subjects

Resistive touchscreen, Multidisciplinary, Fabrication, business.industry, Computer science, Process (computing), technology, industry, and agriculture, Semiconductor device, Conductive atomic force microscopy, Bioinformatics, Article, Optoelectronics, Wafer, business, Nanoscopic scale, Dram

Abstract

We fabricated a novel in-line conductive atomic force microscopy (C-AFM), which can analyze the resistive failures and examine process variance with an exact-positioning capability across the whole wafer scale in in-line DRAM fabrication process. Using this in-line C-AFM, we introduced a new, non-destructive diagnosis for resistive failure in mobile DRAM structures. Specially, we focused on the self-aligned contact (SAC) process, because the failure of the SAC process is one of the dominant factors that induces the degradation of yield performance, and is a physically invisible defect. We successfully suggested the accurate pass mark for resistive-failure screening in the fabrication of SAC structures and established that the cause of SAC failures is the bottom silicon oxide layer. Through the accurate pass mark for the SAC process configured by the in-line C-AFM analyses, we secured a good potential method for preventing the yield loss caused by failures in DRAM fabrication.

Published

2013

10. Gate-Insulator-Capacitance-Dependent Field-Effect Mobility in Solution-Processed Oxide Semiconductor Thin-Film Transistors

Author

Eungkyu Lee, Keon-Hee Lim, Si Yun Park, Kyongjun Kim, and Youn Sang Kim

Abstract

We theoretically and experimentally investigate how the field-effect mobility (MFE) depends on the gate capacitances (CI) in solution-processed oxide semiconductor (OS) thin-film transistors (TFTs). With recently developed solution-based techniques, high quality OS films can be deposited onto flexible substrates at low temperatures, which accelerate applying of flexible, transparent, and ink-jet printable OS TFTs to future mobile display and electronics. Meanwhile, another important issue is to sustainably use of portable devices using integrated OS TFT circuits for a long time. Empirically, Increasing CI has been used to increase the drain current (ID) for high-performance and low-energy consuming OS TFTs, which is based on a theory of conventional metal-oxide-semiconductor field-effect transistors (MOSFETs): ID∝CI. However, it has been observed that incremental features of ID as increasing CI in solution-processed OS TFTs are quite different to that of MOSFETs. It is because disordered metal ions and dense grain boundaries in the solution-processed OSs make MFE depend on total number of accumulated electrons. Thus, MFE relies on CI, and ID cannot be linear relationship to CI. Therefore, grasping the relationship between MFE and CI in theoretical manner is important to realize high-performance, low-operational voltage devices, and it is also useful to design, optimize, and integrate OS TFT circuits. The disordering nature of solution-processed OSs can be classified into nanocrystalline and amorphous states, which are determined by how many numbers of metal ions component are contained. When the number of metal ion component is ‘1’, such as ZnO, InO2, and SnO2, the solution-processed OS films have nanocrystalline phase. As the number of metal ion component is larger than ‘1’(for example, ZnSnO, InGaZnO, InZnO), the states of the OS films are amorphous. Although electronic properties of both amorphous and nanocrystalline OS films arising from their atomic arrangements are different to each other, the CI-dependent-MFE characteristics have been observed by two following features experimentally. First, with high-CI conditions, the maximum-MFE values of the OS TFTs can be achieved with low gate voltages (VG) than that with low-CI conditions. Second, the maximum-MFE values with gate insulator comprising of high-k dielectric materials is higher than that comprising of low-k dielectric materials, within the associated VG regimes. However, how the MFE values is determined by the CI values and how gate-insulator properties (ex, dielectric constant) affects the maximum-MFE values have not been intensively investigated yet. Here, we systematically performed an investigation of the CI-dependent MFE features. We developed theoretical models representative of the solution-processed OS TFTs, where multiple-trapping-and-release (MTR) and hopping percolation mechanisms are used for explaining the electrical conductivity of nanocrystalline and amorphous OS films, respectively. For both theoretical models, we derived a single-piece expression that shows how the MFE value and the operational voltage can be determined by the CI value. We successfully verified the developed analytic formula by using fabricated solution-processed ZnO and ZnSnO TFTs. At low-VG regions (~4 V), the ZnO TFTs shows that its MFE varies from 0.066 to 6.01 cm2 / V sec following MFE ∝~ CI1.66, while the ZnSnO TFTs shows MFE∝~CI0.41. Furthermore, we investigated how the dielectric constant of gate insulators affects the maximum MFE values.

Published

2014

11. Solution- Processed Alkali Metals-Doped Amorphous Zinc Tin Oxide Thin-Film Transistors and Analysis of Alkali Metal Doping Mechanism through the UV-Visible Spectroscopic

Author

Keon-Hee Lim, Eungkyu Lee, Kyongjun Kim, and Youn Sang Kim

Abstract

Recently, alkali metal doped ZnO has received much positive attention owing to its high performance and good electrical stability. In particular, since alkali metals such as Li and Na are general elements and show good potential as doping elements in ZnO semiconductors, several researchers have been interested in alkali metal doping process of polycrystalline zinc oxide semiconductors. However, only a few studies have been reported the doping mechanism to enhance the mobility. In addition, there have been few studies on alkali metal doping mechanism in amorphous metal oxide semiconductors. Most studies about alkali metal doped oxide semiconductor have been inquired in term of crystallinity, oxygen vacancy, and surface morphology properties. For these reasons, we also studied the mechanism of alkali metal doping in view of oxygen vacancy by spectroscopic study using XPS and surface morphology using AFM. However, although we observed that oxygen vacancy contents are reduced slightly with a correlation by interstitial or substitutional mechanism, it seems to be difficult to identify the correlation between the enhancement of electrical properties induced by interstitial doping and the changes of oxygen vacancy contents, because the difference of XPS spectra in doped ZTO films is too small. Also, as the decrease of oxygen vacancy contents means the decrease of electron mobility in metal oxide semiconductors, the tendency of oxygen vacancy spectra in XPS is inconsistence with general phenomena. It means that other mechanisms are required to precisely explain the electrical properties of the doped amorphous ZTO TFTs related to alkali metal doping mechanism. Otherwise, the change in the optical band gap supported by the Burstein-moss theory showed successfully that the enhancement of mobility was related to the interstitial doping of alkali metals. This result shows that the change of the optical band gap clearly applied to the study of the relationship between the change in mobility and interstitial doping concentrations. Here in, we introduce alkali metals doped and solution processed amorphous zinc tin oxide (ZTO) semiconductor TFTs, which show better electrical properties, such as field effect mobility and conductivity, than that of intrinsic amorphous ZTO based TFTs. We also analyze that the doping mechanism of alkali metals in the amorphous ZTO based TFTs using various techniques such as, atomic force microscopy (AFM), X-ray photoemission spectroscopy (XPS), Hall mobility. Furthermore, through the UV-visible spectroscopy, we suggest a comprehensive technique for investigating the enhanced electrical performance induced by alkali metal doping in terms of the change in optical band gap. Specially, we showed that UV-visible spectroscopic analysis for investigating the electrical performance of alkali metal doped metal oxide semiconductor TFTs has good potential as a fast and non-destructive analytical technique.

Published

2014

12. Aqueous zinc ammine complex for solution-processed ZnO semiconductors in thin film transistors

Author

Jeeyoung Yoo, Keon-Hee Lim, Joohee Kim, Youn Sang Kim, Sun-Young Kim, Eungkyu Lee, Kyongjun Kim, and Si Yun Park

Subjects

Reaction mechanism, Materials science, Aqueous solution, business.industry, General Chemical Engineering, Inorganic chemistry, chemistry.chemical_element, Field effect, General Chemistry, Zinc, Crystal structure, Semiconductor, chemistry, Thin-film transistor, business, Dissolution

Abstract

We fabricated zinc oxide (ZnO) TFTs using a zinc ammine complex with various zinc oxide sources such as ZnO, intrinsic Zn(OH)2, and precipitated Zn(OH)2. From the analyses of the reaction mechanism, surface morphology, crystal structure, and oxygen vacancy in the ZnO films, we confirmed the same intermediate in ZnO semiconductor films irrespective of the type of zinc oxide source in the zinc ammine complex precursor. The results showed the analogous value of the average field effect mobility, on/off current ratio, and turn-on voltage in all solution-processed ZnO TFTs. In conclusion, we confirmed that directly dissolving pristine ZnO into ammonia water is the most efficient method for preparing the ZnO semiconductor precursor, the zinc ammine complex, for low-temperature, solution-processed, and high performance ZnO TFTs.

Published

2014

13. Micro-patterned ZnO semiconductors for high performance thin film transistors via chemical imprinting with a PDMS stamp

Author

Kieun Seong, Si Yun Park, Youn Sang Kim, and Kyongjun Kim

Subjects

Fabrication, Materials science, business.industry, Doping, Metals and Alloys, PDMS stamp, Field effect, Sintering, Nanotechnology, General Chemistry, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Semiconductor, Thin-film transistor, Materials Chemistry, Ceramics and Composites, Thin film, business

Abstract

Chemical imprinting was conducted on ZnO semiconductor films via a chemical reaction at the contact regions between a micro-patterned PDMS stamp and ZnO films. In addition, we applied the chemical imprinting on Li doped ZnO thin films for high performance TFTs fabrication. The representative micro-patterned Li doped ZnO TFTs showed a field effect mobility of 4.2 cm(2) V(-1) s(-1) after sintering at 300 °C.

Published

2013

14. Interface engineering for suppression of flat-band voltage shift in a solution-processed ZnO/polymer dielectric thin film transistor

Author

Keon-Hee Lim, Si Yun Park, Kyongjun Kim, Eungkyu Lee, ChaeHo Shin, Joohee Kim, and Youn Sang Kim

Subjects

Materials science, Polymer dielectric, business.industry, General Chemistry, Dielectric, Solution processed, Dipole, Thin-film transistor, Materials Chemistry, Optoelectronics, Flat band, business, Layer (electronics), Voltage

Abstract

Flexible and transparent thin film transistors (FTTFTs) can lead to next generation displays that involve large area, future-oriented flexible and transparent displays. In order to achieve stable FTTFTs, solution processes of organic and inorganic compounds have received significant attention. Above all, transparent oxide semiconductors such as ZnO have been studied to enhance flexibility with high electrical performance by integration with organic dielectrics. However, interfacial traps between inorganic and organic compounds are derived by interface dipole, which induce a considerable flat band shift. Herein, we have developed a self-assembled inorganic layer (SAIL) via the photo-induced transformation of a mono-poly(dimethylsiloxane) (PDMS) layer as interface engineering. Especially, the shifting of flat band voltage (VFB) was effectively suppressed by the SAIL process, which was analyzed with a single-piece analytical model for ZnO TFTs. In addition, flexible ZnO/SAIL/polymer dielectric TFTs with low process temperature as high as 200 °C exhibited a good field-effect mobility μ = 0.28 cm2 V−1 s−1, more than 106 on–off current ratio and excellent device operational stability and flexibility.

Published

2013

15. Water adsorption effects of nitrate ion coordinated Al2O3 dielectric for high performance metal-oxide thin-film transistor

Author

Si Yun Park, Keon-Hee Lim, Kyongjun Kim, Jee Ho Park, Keun Ho Lee, Hong Koo Baik, Young Bum Yoo, and Youn Sang Kim

Subjects

Materials science, Annealing (metallurgy), Materials Chemistry, Analytical chemistry, Ionic bonding, General Chemistry, Dielectric, Thin film, Oxide thin-film transistor, Capacitance, Amorphous solid, Ion

Abstract

A solution-processed ionic amorphous Al2O3 dielectric with a low temperature annealing process at 350 °C shows good compatibility and high performance in metal oxide semiconductor thin film transitors (TFTs) such as Li–ZnO TFTs and In–ZnO TFTs. The Li–ZnO/Al2O3 and In–ZnO/Al2O3 TFTs, with solution-processability and low temperature annealing at a maximum of 350 °C, exhibited field-effect mobilities of 46.9 cm2 V−1 s−1 in crystalline Li–ZnO/Al2O3 TFTs and 44.2 cm2 V−1 s−1 in amorphous In–ZnO/Al2O3 TFTs with an on/off current ratio of more than 105. The proton mobile ion, such as hydrogen ion (H+) from chemisorbed water, in the ionic Al2O3 dielectric remarkably induces a high performance capacitance by the formation of an electrical double layer. The chemisorbed water was monitored by FT-IR and ellipsometric porosimetry measurements. Furthermore, the addition of H2O2 to the ionic Al2O3 dielectric precursor successfully suppressed the oxygen vacancies in the dielectric layer, which caused the electrical trap and pass, and confirmed the stable operation. These ionic amorphous Al2O3 dielectrics show good potential as switching TFTs devices in advanced displays, because they can satisfy the various demands of next-generation high-performance TFTs, such as low-cost, solution-processability, and a relatively low-temperature process.

Published

2013

16. The structural, optical and electrical characterization of high-performance, low-temperature and solution-processed alkali metal-doped ZnO TFTs

Author

Kyongjun Kim, Jeong Ho Cho, Keon-Hee Lim, Si Yun Park, Eungkyu Lee, Beom Joon Kim, and Youn Sang Kim

Subjects

Electron mobility, Materials science, business.industry, Band gap, Doping, Fermi level, Analytical chemistry, Field effect, Biasing, General Chemistry, symbols.namesake, Semiconductor, X-ray photoelectron spectroscopy, Materials Chemistry, symbols, business

Abstract

The structural, electrical and optical properties of high-performance, low-temperature and solution-processed alkali metal-doped ZnO TFTs were studied using various analytic instruments, including HR-TEM, AFM, XPS, EDS, electrical bias stability test and UV-vis spectroscopy. Furthermore, we successfully demonstrated that a change in the optical bandgap energy of Li-doped ZnO semiconductor films supported by Burstein–Moss theory can show a trade-off relationship between the field effect mobility of Li-ZnO TFTs and the Li doping concentrations. The relative broadening of the Eopt values, which are strongly related to the amount of excited electrons from the Fermi level in the valance band to the conduction band, was observed from the undoped ZnO film to the Li-doped ZnO film (10 mol%). The increase in the electron donor concentration was the dominant reason for the enhancement in the electron mobility of the alkali metal-doped ZnO TFTs.

Published

2013

17. Alkali earth metal dopants for high performance and aqueous-derived ZnO TFT

Author

Si Yun Park, Seonjo Kim, Keon-Hee Lim, Kyongjun Kim, Youn Sang Kim, Hyungjun Kim, and Eungkyu Lee

Subjects

Alkaline earth metal, Materials science, Aqueous solution, Chemical engineering, Dopant, Thin-film transistor, General Chemical Engineering, Doping, Inorganic chemistry, Field effect, Electrical performance, General Chemistry

Abstract

We introduce high performance, low-temperature (

Published

2013

18. Piezoelectric Materials: All‐Solution‐Processed Flexible Thin Film Piezoelectric Nanogenerator (Adv. Mater. 45/2012)

Author

Sung Yun Chung, Seok-Jin Yoon, Sun-Young Kim, Kyongjun Kim, Chong Yun Kang, Youn Sang Kim, Sang-Woo Kim, and Ju-Hyuck Lee

Subjects

Materials science, Mechanics of Materials, Mechanical Engineering, Nanogenerator, General Materials Science, Thin film, Composite material, Piezoelectricity, Solution processed

Published

2012

19. Low temperature and solution-processed Na-doped zinc oxide transparent thin film transistors with reliable electrical performance using methanol developing and surface engineering

Author

Kyongjun Kim, Si Yun Park, Jae Min Myoung, ChaeHo Shin, Youn Sang Kim, and Keon-Hee Lim

Subjects

Materials science, Aqueous solution, business.industry, Doping, Oxide, Sintering, Nanotechnology, General Chemistry, Surface engineering, law.invention, chemistry.chemical_compound, Hysteresis, chemistry, Thin-film transistor, law, Materials Chemistry, Optoelectronics, Photolithography, business

Abstract

A transparent thin film transistor (TTFT), including zinc oxide (ZnO), has come into the spotlight as an innovative TFT that has the potential to drive the future of the information technology industry. Herein, we developed a new direct patterning method, drop-casting with a new developing method, through the combination of an aqueous ammonia–ZnO process with the doping of Na ions and surface engineering for high n-type semiconducting performance with good operational stability at low temperature. In particular, the effective decomposition and removal of the residual ammonia compounds using methanol have a successful effect on both intrinsic and Na doped ZnO precursor processes for TFTs and they showed the extensive possibility of ammonia based metal oxide precursor solutions. In this method, the Na doped ZnO TTFTs showed good operational stability even with the process of low temperature sintering. The mobility μ = 0.80 cm2 V−1 s−1 was obtained at 200 °C sintering and the mobility μ = 0.10 cm2 V−1 s−1 at 100 °C sintering. In addition, in ambient conditions, the patterned Na doped ZnO TTFT exhibited high electron mobility μ = 1.84 cm2 V−1 s−1 with excellent device operational stability and scant hysteresis with sintering at 300 °C. This method is not only simple as compared with photolithography and inkjet printing, but is also a sophisticated patterning process with good fidelity for solution-processed ZnO TFTs. Moreover, the proposed method can be extended to plastic substrates on a large scale because of the low temperature development process of the ammonia–ZnO precursor using methanol and continuous patterning at ambient conditions. We believe that this method can be adapted to the advanced process toward future printed transparent electronic devices.

Published

2012

20. Fast, exact, and non-destructive diagnoses of contact failures in nano-scale semiconductor device using conductive AFM.

Author

ChaeHo Shin, Kyongjun Kim, JeongHoi Kim, Wooseok Ko, Yusin Yang, SangKil Lee, Chung Sam Jun, and Youn Sang Kim

Subjects

*SEMICONDUCTOR devices, *ATOMIC force microscopy, *SEMICONDUCTORS, *SILICON oxide, *NANOELECTROMECHANICAL systems

Abstract

We fabricated a novel in-line conductive atomic force microscopy (C-AFM), which can analyze the resistive failures and examine process variance with an exact-positioning capability across the whole wafer scale in in-line DRAM fabrication process. Using this in-line C-AFM, we introduced a new, non-destructive diagnosis for resistive failure in mobile DRAM structures. Specially, we focused on the self-aligned contact (SAC) process, because the failure of the SAC process is one of the dominant factors that induces the degradation of yield performance, and is a physically invisible defect. We successfully suggested the accurate pass mark for resistive-failure screening in the fabrication of SAC structures and established that the cause of SAC failures is the bottom silicon oxide layer. Through the accurate pass mark for the SAC process configured by the in-line C-AFM analyses, we secured a good potential method for preventing the yield loss caused by failures in DRAM fabrication. [ABSTRACT FROM AUTHOR]

Published

2013