Rapid Thermal Annealing Method Research Articles

Impact of post-ion implantation annealing on Se-hyperdoped Ge

Hyperdoped germanium (Ge) has demonstrated increased sub-bandgap absorption, offering potential applications in the short-wavelength-infrared spectrum (1.0–3.0 μm). This study employs ion implantation to introduce a high concentration of selenium (Se) into Ge and investigates the effects of post-implantation annealing techniques on the recovery of implantation damage and alterations in optical properties. We identify optimal conditions for two distinct annealing techniques: rapid thermal annealing (RTA) at a temperature of 650 °C and ultrafast laser heating (ULH) at a fluence of 6 mJ/cm2. The optimized ULH process outperforms the RTA method in preserving high doping profiles and achieving a fourfold increase in sub-bandgap absorption. However, RTA leads to regrowth of single crystalline Ge, while ULH most likely leads to polycrystalline Ge. The study offers valuable insights into the hyperdoping processes in Ge for the development of advanced optoelectronic devices.

Structural phase transition and resistive switching properties of Cu x O films during post-thermal annealing

We studied the phase change and resistive switching characteristics of copper oxide (Cu x O) films through post-thermal annealing. This investigation aimed to assess the material’s potential for a variety of electrical devices, exploring its versatility in electronic applications. The Cu x O films deposited by RF magnetron sputtering were annealed at 300, 500, and 700 °C in ambient air for 4 min by rapid thermal annealing (RTA) method, and then it was confirmed that the structural phase change from Cu2O to CuO occurred with increasing annealing temperature. Resistive random-access memory (ReRAM) devices with Au/Cu x O/p+-Si structures were fabricated, and the ReRAM properties appeared in CuO-based devices, while Cu2O ReRAM devices did not exhibit resistive switching behavior. The CuO ReRAM device annealed at 500 °C showed the best properties, with a on/off ratio of 8 × 102, good switching endurance of ∼100 cycles, data retention for 104 s, and stable uniformity in the cumulative probability distribution. This characteristic change could be explained by the difference in the grain size and density of defects between the Cu2O and CuO films. These results demonstrate that superior and stable resistive switching properties of RF-sputtered Cu x O films can be obtained by low-temperature RTA.

Effect of rapid thermal annealing on the surface properties of the microlens arrays machined on monocrystalline silicon

Microstructure arrays, such as microlens arrays, play a significant role in optical systems, biomedical imaging, and telecommunications. However, the machining-induced subsurface defects deteriorate their performance and functionality. To address this issue, this study proposes a rapid thermal annealing method to heal the subsurface defects using different temperatures ranging from 200 °C to 1000 °C in a vacuum. Firstly, the ultra-precision diamond sculpturing process is employed to machine the high-quality microlens array on the monocrystalline silicon surface. Then, the effects of the rapid thermal annealing on the microlens array surface, such as surface roughness and subsurface defect, are comprehensively investigated. Experimental results show that the annealing temperature of >600 °C contributes to the decrease in surface roughness and subsurface defect. Furthermore, to reveal the healing mechanism, a molecular dynamics simulation of rapid thermal annealing is performed by controlling the bulk temperature of machined monocrystalline silicon from 500 K to 1300 K. The simulation results show that recrystallization always occurred on the interface between the amorphous layer and monocrystalline silicon substrate and the healing mechanism should be solid phase epitaxy rather than random nucleation. The research findings would contribute to fabricating the defect-free optical lens in the industry.

PVA-Coated AgNPs/SiO2 for Detection of Gentian Violet with High Sensitivity

Improving the detection limit of surface-enhanced Raman scattering (SERS) is a significant issue for the design and application of plasmon substrate. It always suffers from the weak affinity of probe molecules on the nanoscale surface, uncontrollable aggregation behaviors of nanoparticles, and strong fluorescence of the detected substance. In this paper, AgNPs/SiO2 substrate is prepared by a rapid thermal annealing method with a mean size of 87.9 ± 30.7 nm. A layer of 5–30 nm PVA (polyvinyl alcohol) film is used as the stabilizer of AgNPs. With PVA coating, AgNPs can improve the detection limit of gentian violet by three magnitudes, compared with the one on undecorated AgNPs which is just 10−5 mol/L. In the sensitive detection using coated AgNPs/SiO2 substrate, PVA possibly plays three significant roles, affinity increaser between gentian violet and silver nanoparticles, fluorescence inhibiter of gentian violet, and stabilizer of Ag nanoparticles. The results provide a modification method for improving SERS sensitivity of plasmon substrate, which uses convenient and low-cost rapid thermal annealing as the patterning method and PVA as the coater, an advantageous technology for plasmon substrate application into trace detection.

Combining plasmon-enhanced fluorescence with Rayleigh surface acoustic waves to quantify Carcinoembryonic Antigen from human plasma

To improve the direct quantification of Carcinoembryonic Antigen (CEA) from body fluids by immunofluorescence, a surface acoustic wave (SAW) based biosensor was developed combined with an optimized silver nanostructure at the sensing region. Fluorescence signal amplification is achieved by patterning silver nanostructures using the rapid thermal annealing (RTA) method. In addition, the problem of background noise interference from nonspecific binding in human plasma is addressed by Rayleigh wave streaming at the immunoassay region, which shows a reduction in the limit of detection. The results show that the silver nanostructures significantly increase the sensor sensitivity by 49.99-fold and lower the limit of detection of CEA in phosphate buffered saline (PBS) solution to 101.94 pg/mL. The limit of detection of CEA biomarker in human plasma was successfully brought down to 11.81 ng/mL by reducing background noise using Rayleigh SAW streaming. This allows for a point-of-need sensor system to be realized in various clinical biosensing applications.

Aging study on BiFe0.95Mn0.05O3 ferroelectric thin films with different preferred orientations

The BiFe0.95Mn0.05O3 (BFMO) thin films were epitaxial grown on the SrRuO3/LaAlO3 (SRO/LAO) single crystal substrates with different orientations (<100 >,<110 >and<111 >) by sol-gel and layer-by-layer rapid thermal annealing methods, respectively. The test techniques including X-ray diffraction (XRD), Raman, high resolution field emission scanning electron microscope (HR-SEM) and atomic force microscope (AFM) were applied to analyze the structure of the film samples. The results showed that a two-phase coexistence structure grown in all three films with the rhombohedral R3c as the main phase and the orthogonal Pnma as the second phase. The PFM tests revealed that the <111> oriented sample had normal island domain configuration, while the <100> and <110> oriented samples mainly grew non-180° domains. By comparing the aging behavior of the three samples after a room temperature period of aging for 30 and 120 days, it was believed that the film samples with different orientations appeared distinct aging degrees due to the different number of polarized equivalent components along <111> direction and the different angle between the equivalent components and the applied electric field direction. In particular, the film sample with <111> orientation showed almost no aging. It was also believed that the defect dipole pinning happened in the ferroelectric domain bodies would play a leading role in the aging process.

Low-power alternating-current electroluminescence from Ga2O3:Tb3+/SiOx-based metal-oxide-silicon structure by rapid thermal annealing method and solution-based technique

Alternating-current (AC) metal-oxide-semiconductor electroluminescence (MOS-EL) device with Ga2O3:Tb3+/SiOx oxide layers on a silicon (Si) substrate has been demonstrated by a solution-based spin-coating technique followed with rapid thermal annealing (RTA) process. The oxide films were optimized in the Tb3+ concentration of 0.5 at.% and RTA temperature of 900 ℃, which revealed that the monoclinic β-Ga2O3 with a thickness of 85 nm was formed on the Si substrate accompanied by the amorphous SiOx layer with a thickness of 8 nm. The MOS-EL device started to operate at 6 V (corresponding to 0.63×106 V/cm in an electric field) under the sinusoidal waveform of 400 Hz with green emission attributed to the f-f transitions of Tb3+ ions. The EL behavior revealed asymmetric optical and electrical characteristics due to the asymmetrical double oxide structure and short-term reliability with optical maintenance of 80% for 60 min without any encapsulation.

Ultraviolet-Assisted Low-Thermal-Budget-Driven α-InGaZnO Thin Films for High-Performance Transistors and Logic Circuits.

Developing a low-temperature fabrication strategy of an amorphous InGaZnO (α-IGZO) channel layer is a prerequisite for high-performance oxide-based thin film transistor (TFT) flexible device applications. Herein, an ultraviolet-assisted oxygen ambient rapid thermal annealing method (UV-ORTA), which combines ultraviolet irradiation with rapid annealing treatment in an oxygen atmosphere, was proposed to realize the achievement of high-performance α-IGZO TFTs at low temperature. Experimental results have confirmed that UV-ORTA treatment has the ability to suppress defects and obtain high-quality films similar to high-temperature-annealing-treated samples. α-IGZO/HfAlO TFTs with high-performance and low-voltage operating have been achieved at a low temperature of 180 °C for 200 s, including a high μsat of 23.12 cm2 V-1 S-1, large Ion/off of 1.1 × 108, small subthreshold swing of 0.08 V/decade, and reliable stability under bias stress, respectively. As a demonstration of complex logic applications, a low-voltage resistor-loaded unipolar inverter based on an α-IGZO/HfAlO TFT has been built, demonstrating full swing characteristics and a high gain of 13.8. Low-frequency noise (LFN) characteristics of α-IGZO/HfAlO TFTs have been presented and concluded that the noise source tended to a carrier number fluctuation (ΔN) model from a carrier number and correlated mobility fluctuation (ΔN-Δμ) model. As a result, it can be inferred that the low-temperature UV-ORTA technique to improve α-IGZO thin film quality provides a facile and designable process for the integration of α-IGZO TFTs into a flexible electronic system.

Design and fabrication of frequency-responsive terahertz transmittance modulator based on vanadium dioxide spherical films

In this paper, a spherical film array structure based on vanadium dioxide (VO2) was designed and fabricated aimed to enhance the frequency response of transmittance in terahertz (THz) band of VO2 films. Vanadium dioxide and vanadium pentoxide composite spherical films were grown on the surface of two-dimensional single layer array of SiO2 sphere by magnetron sputtering and rapid thermal annealing method, and the frequency response of transmittance of spherical films was studied. The THz transmittance modulation depth (MD) of spherical films increased significantly in the 1.5–3 THz range as frequency increased, while MD of planar films only increased slightly throughout the frequency band. We attributed the frequency response of the MD of spherical films to the absorption by electric dipole resonance. The numerical simulations and electric field distributions illustrate that the regulating effect of resonance absorption would increase as the width of spherical gaps increase. When the width of the spherical gaps was 0.05μm, the absorptivity would increase by 120% from 1.5 to 3 THz, showing the possibility of further improving the THz MD of spherical films. This research would provide a good candidate material in the active modulation in terahertz band which broaden a path for dynamic terahertz radiation manipulation devices.

HVPE growth of bulk GaN with high conductivity for vertical devices

The electrical properties of gallium nitride (GaN) substrate are crucial to the performance of vertical power devices. Bulk GaN substrates with carrier concentrations in the range from 6.7 × 1017 to 1.7 × 1019 cm−3 are grown by hydride vapor phase epitaxy. All samples show no obvious tensile stress regardless of the carrier concentration. Moreover, the mobility of Si-doped high-quality bulk GaN is superior to the GaN template with higher dislocation density at the same carrier concentration. The influence of carrier concentration on the performance of ohmic contact on N-face of Si-doped GaN is also carefully studied by circular transfer length measurement and rapid thermal annealing methods. The specific contact resistivity decreases monotonically with increase of carrier concentration, while it increases with the annealing temperature. The N-face contact becomes non-ohmic when the annealing temperature exceeds the limit value, which increases with the carrier concentration. The sample with carrier concentration of 1.7 × 1019 cm−3 still showed ohmic behavior after annealing at 450 °C. These results are not only useful to improve the electrical properties of N-type bulk GaN substrate, but also provide a potential solution for improving the efficiency of vertical devices in the future.

Application of gallium oxide-based UV detector in complex topography and geological exploration

In order to overcome the problem that the current geological exploration cannot detect complex geology effectively, a method of complex topographic geological exploration based on gallium oxide-based ultraviolet detector is proposed. On the surface of gallium oxide thin film, the dispersed aluminum nanoparticles are formed by a rapid thermal annealing method to prepare gallium oxide-based UV detector. The prepared UV detector is applied in the exploration of complex topography and geology, and the calibration conditions of geological exploration are determined. The appropriate UV detector probe is selected according to the calibration conditions. After the calibration conditions and probe are determined, the complex terrain is corrected by 3Mnnaert correction model, and the complex terrain is classified by multi-UV spectral band to realize the complex terrain geological exploration. The Maliba Reservoir in Yunnan Province with complex topography is selected as the experimental object. The experimental results show that the method can effectively explore the geological problems such as seepage, seepage stability, soil liquefaction, and uneven settlement of dam foundation in the experimental area.

Nanocrystals Embedded High-k Nonvolatile Memories Prepared By Pulsed Rapid Annealing

Nonvolatile memories (NVMs) made of MOS capacitors with nanocrystals embedded high-k gate dielectrics have been reported [1-7]. Nanocrystals made of various types of materials, e.g., Si, ITO, ZnO, RuO, CdS, and CdSe, were used as the charge trapping media in the device [1,5]. Both holes and electrons can be stored in this kind of device. Depending on the band structure and charge affinity of the nanocrystal material, samples can preferentially trap one type of charges over the other type of charges. For example, the nc-ITO or nc-MoOx embedded samples prefer to trap holes [6]. On the other hand, the nc-RuO embedded sample prefers to trap electrons [7]. There are many methods in preparing the nanocrystals embedded dielectric structure. Previously, our group has used the in-situ crystallization method to prepare the sample, i.e., forming embedded nanocrystals by annealing a tri-layer thin layer structure. The originally continuous thin embedded layer was transformed into discrete nanocrystals after a high temperature treatment. However, if the annealing time is long, the thermal budget can be large, which affects the interface layer formation and the dopant distribution in the substrate. A low thermal budget pulsed rapid thermal annealing (PRTA) method has been used to transform the amorphous silicon into polycrystalline for the thin film transistor (TFT) and solar cell applications [8]. In this paper, the PRTA method is used to form nanocrystals embedded high-k dielectric for the nonvolatile memory application. The Zr-doped HfO2 (ZrHfO) high-k film is used as the dielectric for its excellent bulk and interface properties, e.g., higher crystallization temperature, larger effective k value, and fewer interface states [1].The ZrHfO/ZnO/ZrHfO tri-layer was sputter deposited on a dilute HF cleaned p-type Si (100) (1015 cm3) wafer in one pumpdown without breaking the vacuum. The ZrHfO layer was sputtered from a Zr/Hf target (12:88 wt%) in Ar/O2 (1:1) at 5 mTorr, 60W for 2 min (bottom) or 10 min (top layer), The ZnO layer was sputtered from a ZnO target in Ar/O2 at 5 mTorr, 60W for 3 min. The tri-layer was treated with a PRTA process of 10 cycles of 800ºC heating-1 second cooling under N2 atmosphere. A control sample that contained only the ZrHfO gate dielectric was also prepared with the same deposition and PRTA process for comparison. The complete MOS capacitor was complete after the aluminum (Al) gate electrode was defined and treated with a post metal annealing (PMA) step at 400ºC under the H2/N2 (1:9) for 5min. The back side of the Si wafer was deposited with an Al contact layer. Charge trapping characteristics were determined from the C-V hysteresis curves.Figure 1 shows TEM cross-sectional views of (a) control and (b) nc-ZnO embedded samples. The ZrHfO layer remains amorphous and a thick amorphous interface layer was formed underneath it. The PRTA treated tri-layer contains discrete nc-ZnO dots, as shown in Fig. 1(b). Separately, the XRD pattern shows that the nc-ZnO has the (100) crystalline structure. The ZrHfO layer is amorphous and the interface layer thickness is about the same as that of the control sample.The control sample, i.e., with the ZrHfO gate dielectric layer, shows very small C-V hysteresis. However, the nc-ZnO embedded sample shows visible C-V hysteresis. Figure 2 shows that when the gate voltage (Vg ) was swept from positive (+Vg ) to negative (-Vg ), i.e., forward, and then to positive (+Vg ), i.e., backward, the gap of the flat band voltages (VFB ’s) was increased. In addition, when swept under the same Vg range, the shift of the VFB in the backward direction is larger than that in the forward direction. Therefore, the charge trapping capacity of the nc-ZnO is dependent on the supply of the amount of charges injected from the substrate.Other charge trapping characteristics, such as the memory windows of the control and nc-ZnO embedded samples as well as the time dependent charge retentions of electrons and holes, will be discussed.[1] Y. Kuo, ECS Trans., 35(3), 13 (2011).[2] Y. Maeda, et al., Appl. Phys. Lett., 59, 3168 (1991).[3] J. Lu, Y. Kuo, J. Yan, and C.-H. Lin, JJAP, 45(34), L901 (2006).[4] C.-H. Yang, Y. Kuo, and C.-H. Lin, APL, 96, 192106 (2010).[5] S. Zhang and Y. Kuo, ECS JSS, 7 (5), Q97 (2018).[6] Y. Kuo, ECS Trans., 66(5), 139 (2015).[7] C.-H. Lin and Y. Kuo, MRS Proc., 1250, G01-08 (2010).[8] Y. Kuo, C.-C. Lin, and S Verkhoturov, 38th IEEE PVSC Proc., 000342 (2011). Figure 1

Plasmon–exciton coupling of monolayer MoSe2 with self-organized metallic nanoparticles

We report the fabrication of self-organized metallic Ag nanoparticles (NPs) on monolayer MoSe2 surface using rapid thermal annealing method. The optical properties of monolayer MoSe2 and hybrid MoSe2–Ag NP structure are investigated and compared. It is found that significant enhancement of Raman scattering and photoluminescence is achieved by hybridizing monolayer MoSe2 with self-organized Ag NPs. The enhancement mechanism is demonstrated to be plasmon–exciton coupling based on the theoretical simulations using finite-difference time-domain method.

Rapid thermal annealing assisted facile solution method for tungsten-doped vanadium dioxide thin films on glass substrate

Abstract Vanadium dioxide VO2 is an important thermochromic material with useful applications in smart energy devices. This paper describes the synthesis of high-quality vanadium dioxide thermochromic thin films directly on glass substrate without any barrier layer prepared using a simple solution method. We demonstrate that 50 nm thick VO2 films display excellent visible transmittance (76.9% on glass, 69.4% on fused silica) and a large NIR switching efficiency (33.8% on glass, 44.3% on fused silica) at 1600 nm. It is found that the metal to semiconductor phase transition temperature Tc of undoped films can be reduced from a theoretical value of 68 °C to 49.4 °C by rapid thermal annealing. With W doping a continuous drop in the Tc is observed and for VO2 with 2% W doping, a Tc of 25.8 °C is achieved. These good optical properties and the near room-temperature phase transition temperature suggest that solution processing with the rapid thermal annealing process is a feasible method to obtain this promising material on glass substrate for practical application in thermochromic smart windows.

Photoelectrochemical Hydrogen Evolution and CO2 Reduction over MoS2/Si and MoSe2/Si Nanostructures by Combined Photoelectrochemical Deposition and Rapid-Thermal Annealing Process

Diverse methods have been employed to synthesize MoS2 and MoSe2 catalyst systems. Herein, a combined photoelectrochemical (PEC) deposition and rapid-thermal annealing process has first been employed to fabricate MoS2 and MoSe2 thin films on Si substrates. The newly developed transition-metal dichalcogenides were characterized by scanning electron microscopy, Raman spectroscopy and X-ray photoelectron spectroscopy. PEC hydrogen evolution reaction (HER) was demonstrated in an acidic condition to show a PEC catalytic performance order of MoOx/Si &lt; MoS2/Si &lt;&lt; MoSe2/Si under the visible light-on condition. The HER activity (4.5 mA/cm2 at −1.0 V vs Ag/AgCl) of MoSe2/Si was increased by 4.8× compared with that under the dark condition. For CO2 reduction, the PEC activity was observed to be in the order of MoS2/Si &lt; MoOx/Si &lt;&lt; MoSe2/Si under the visible light-on condition. The reduction activity (0.127 mA/cm2) of MoSe2/Si was increased by 9.3× compared with that under the dark condition. The combined electrochemical deposition and rapid-thermal annealing method could be a very useful method for fabricating a thin film state catalytic system perusing hydrogen production and CO2 energy conversion.

From Fancy Blue to Red: Controlled Production of a Vibrant Color Spectrum of Fluorescent Diamond Particles

AbstractThe current study reports a breakthrough method for production of multicolor diamond particulates using a rapid thermal annealing (RTA) approach with precise temperature and time control, enabling annealing of diamond particulates up to 2100 °C without extensive graphitization. The RTA method generates conditions which allow formation of one‐, two‐, and three‐atom nitrogen complexes with vacancies in electron irradiated type Ib synthetic diamond, providing vibrant luminescence in the red, green, and blue spectral ranges, correspondingly. Controlled and highly reproducible formation of specific color centers previously not possible in type Ib synthetic diamond particles opens new opportunities for particulate diamond in a plethora of fluorescence imaging applications in biological and industrial fields.

Thin dysprosium oxide films formed by rapid thermal annealing on porous SiC substrate

In this paper, we consider the effect of rapid thermal annealing (RTA) on the properties of Dy2O3 film formed on the surface of a substrate with a por-SiC/SiC structure. The atomic composition of the films under study was analyzed as a function of the RTA time. It is shown that the RTA method makes it possible to obtain thin Dy oxide films with a composition close to the stoichiometric one. In this case, an increase in the RTA time leads to improving the quality of film-substrate interface and increasing the optical transmission of Dy2O3/por-SiC/SiC structure

Enhanced hole concentration in nonpolar a-plane p-AlGaN film with multiple-step rapid thermal annealing technique

An innovative multiple-step rapid thermal annealing (RTA) technique was developed for obtaining high hole concentration in the nonpolar a-plane Mg-delta-doped AlGaN films grown on semi-polar r-plane sapphire substrates with metal organic chemical vapor deposition. The structural, optical, and electrical properties of the nonpolar a-plane p-AlGaN epi-layers were characterized with high-resolution x-ray diffraction, photoluminescence spectra, and Hall effect measurement. The characterization results demonstrated that the dissociation efficiency of the Mg–H bonds in the nonpolar a-plane p-AlGaN films could be improved significantly with the multiple-step RTA process. In fact, a hole concentration as high as 1.9 × 1018 cm−3 was achieved with the multiple-step RTA technique, which was 35%, 9%, and 23% higher than those obtained with conventional one-step, two-step, and the recently renovated two-step RTA methods, respectively.

Efficient Electrochemical Potentiostatic Activation Method for GaN-Based Green Vertical-LEDs

An efficient electrochemical potentiostatic activation (EPA) method was designed and performed for hydrogen atoms removal from inside a Mg-doped gallium nitride (GaN) layer of green vertical light-emitting diodes (V-LEDs). The EPA method was conducted at the potentiostatic conditions of 2, 3, and 5 V for 5 mins. The role of the applied voltage value in the breaking of the Mg-H complexes and in increasing the holes concentration inside the p-GaN layer in terms of LED device performances was investigated. The internal quantum efficiency (IQE) of the green V-LEDs behaved inversely with the applied voltage. The IQE of green V-LEDs EPA processed with a low voltage of 2 V realized an improvement of about 6% and only about 2.5% for green V-LEDs EPA processed with a high voltage of 5 V at an injection current of 100 mA compared to the conventional rapid thermal annealing method. The light output power achieved the highest enhancement of about 10.5% at 100 mA when applying the lowest voltage of 2 V, which originated from an improvement of the IQE. The forward voltage was also reduced after the EPA process. The developed EPA method was proven to effectively improve the external quantum efficiency of green V-LEDs.

The fabrication and visible–near-infrared optical modulation of vanadium dioxide/silicon dioxide composite photonic crystal structure

We demonstrated a visible and near-infrared light tunable photonic nanostructure, which is composed of vanadium dioxide (VO2) thin film and silicon dioxide (SiO2) ordered nanosphere arrays. The vanadium films were sputtered on two-dimensional (2D) SiO2 sphere arrays. VO2 thin films were prepared by rapid thermal annealing (RTA) method with different oxygen flow rates. The close-packed VO2 shell formed a continuous surface, the composition of VO2 films in the structure changed when the oxygen flow rates increased. The 2D VO2/SiO2 composite photonic crystal structure exhibited transmittance trough tunability and near-infrared (NIR) transmittance modulation. When the oxygen flow rate increased from 3 slpm to 4 slpm, the largest transmittance trough can be regulated from 904 to 929 nm at low temperature, the transmittance troughs also appear blue shift when the VO2 phase changes from insulator to metal. The composite nanostructure based on VO2 films showed visible transmittance tunability, which would provide insights into the glass color changing in smart windows.