Super-transition-array calculations for synthetic spectra and opacity of high-density, high-temperature germanium plasmas

Abstract As DRAM technology extends into 12-inch diameter wafer processing, plasma-induced wafer charging is a serious problem in DRAM volume manufacture. There are currently no comprehensive reports on the potential impact of plasma damage on high density DRAM reliability. In this paper, the possible effects of floating potential at the source/drain junction of cell transistor during high-field charge injection are reported, and regarded as high-priority issues to further understand charging damage during the metal pad etching. The degradation of block edge dynamic retention time during high temperature stress, not consistent with typical reliability degradation model, is analyzed. Additionally, in order to meet the satisfactory reliability level in volume manufacture of high density DRAM technology, the paper provides the guidelines with respect to plasma damage. Unlike conventional model as gate antenna effect, the cell junction damage by the exposure of dummy BL pad to plasma, was revealed as root cause.

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High-density Néel-type magnetic skyrmion phase stabilized at high temperature

NPG Asia Materials ◽

10.1038/s41427-020-00270-z ◽

2020 ◽

Vol 12 (1) ◽

Author(s):

Hee Young Kwon ◽

Kyung Mee Song ◽

Juyoung Jeong ◽

Ah-Yeon Lee ◽

Seung-Young Park ◽

...

Keyword(s):

High Temperature ◽

High Density ◽

Low Density ◽

Memory Devices ◽

Magnetic Multilayer ◽

Multilayer Systems ◽

Micromagnetic Simulations ◽

Transmission Electron ◽

Ultrahigh Density ◽

Lorentz Transmission Electron Microscopy

AbstractThe discovery of a thermally stable, high-density magnetic skyrmion phase is a key prerequisite for realizing practical skyrmionic memory devices. In contrast to the typical low-density Néel-type skyrmions observed in technologically viable multilayer systems, with Lorentz transmission electron microscopy, we report the discovery of a high-density homochiral Néel-type skyrmion phase in magnetic multilayer structures that is stable at high temperatures up to 733 K (≈460 °C). Micromagnetic simulations reveal that a high-density skyrmion phase can be stabilized at high temperature by deliberately tuning the magnetic anisotropy, magnetic field, and temperature. The existence of the high-density skyrmion phase in a magnetic multilayer system raises the possibility of incorporating chiral Néel-type skyrmions in ultrahigh-density spin memory devices. Moreover, the existence of this phase at high temperature shows its thermal stability, demonstrating the potential for skyrmion devices operating in thermally challenging modern electronic chips.

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Manufacturability Study for Etching High-Density BST/Pt Capacitors

MRS Proceedings ◽

10.1557/proc-655-cc6.6.1 ◽

2000 ◽

Vol 655 ◽

Author(s):

Jay Hwang

Keyword(s):

High Temperature ◽

Etch Rate ◽

Control Process ◽

High Density ◽

Wafer Surface ◽

Plasma Chamber ◽

Reactive Plasma ◽

Pt Electrodes ◽

Profile Control

AbstractProfile control, process repeatability and productivity concerns in etching Pt electrodes are reviewed specifically for application in fabricating high-density BST/Pt capacitors. The approach of using a high temperature cathode in a high-density reactive plasma chamber has produced a repeatable >85° Pt profile, stable etch rate and low particle results over a 500-wafer marathon test. A “corrosion-like” BST defect can be prevented by adding a post etch treatment to remove any corrosive residue from the wafer surface. A feasible manufacturing solution for etching BST/Pt capacitors for future high-density DRAM application is demonstrated.

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The Feasibility for Potassium-Based Phosphate Brines To Serve as High-Density Solid-Free Well-Completion Fluids in High-Temperature/High-Pressure Formations

SPE Journal ◽

10.2118/194008-pa ◽

2018 ◽

Vol 24 (05) ◽

pp. 2033-2046 ◽

Cited By ~ 1

Author(s):

Hu Jia ◽

Yao–Xi Hu ◽

Shan–Jie Zhao ◽

Jin–Zhou Zhao

Keyword(s):

High Pressure ◽

High Temperature ◽

Oil And Gas ◽

Pressure Coefficient ◽

High Density ◽

Well Drilling ◽

Well Completion ◽

Oil And Gas Resources ◽

Completion Fluids ◽

High Temperature High Pressure

Summary Many oil and gas resources in deep–sea environments worldwide are often located in high–temperature/high–pressure (HT/HP) and low–permeability reservoirs. The reservoir–pressure coefficient usually exceeds 1.6, with formation temperature greater than 180°C. Challenges are faced for well drilling and completion in these HT/HP reservoirs. A solid–free well–completion fluid with safety density greater than 1.8 g/cm3 and excellent thermal endurance is strongly needed in the industry. Because of high cost and/or corrosion and toxicity problems, the application of available solid–free well–completion fluids such as cesium formate brines, bromine brines, and zinc brines is limited in some cases. In this paper, novel potassium–based phosphate well–completion fluids were developed. Results show that the fluid can reach the maximum density of 1.815 g/cm3 at room temperature, which makes a breakthrough on the density limit of normal potassium–based phosphate brine. The corrosion rate of N80 steel after the interaction with the target phosphate brine at a high temperature of 180°C is approximately 0.1853 mm/a, and the regained–permeability recovery of the treated sand core can reach up to 86.51%. Scanning–electron–microscope (SEM) pictures also support the corrosion–evaluation results. The phosphate brine shows favorable compatibility with the formation water. The biological toxicity–determination result reveals that it is only slightly toxic and is environmentally acceptable. In addition, phosphate brine is highly effective in inhibiting the performance of clay minerals. The cost of phosphate brine is approximately 44 to 66% less than that of conventional cesium formate, bromine brine, and zinc brine. This study suggests that the phosphate brine can serve as an alternative high–density solid–free well–completion fluid during well drilling and completion in HT/HP reservoirs.

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Precise Chip Joint Method with Sub-micron Au Particle for High-density SiC Power Module Operating at High Temperature

Additional Conferences (Device Packaging HiTEC HiTEN & CICMT) ◽

10.4071/hiten-wa17 ◽

2013 ◽

Vol 2013 (HITEN) ◽

pp. 000254-000259 ◽

Cited By ~ 2

Author(s):

Fumiki Kato ◽

Fengqun Lang ◽

Simanjorang Rejeki ◽

Hiroshi Nakagawa ◽

Hiroshi Yamaguchi ◽

...

Keyword(s):

Shear Strength ◽

High Temperature ◽

Flip Chip ◽

Stress Test ◽

High Density ◽

Cathode Side ◽

Module Structure ◽

Power Devices ◽

Power Module ◽

Joint Method

In this work, a novel precise chip joint method using sub-micron Au particle for high-density silicon carbide (SiC) power module operating at high temperature is proposed. A module structure of SiC power devices are sandwiched between two silicon nitride-active metal brazed copper (SiN-AMC) circuit boards. To make a precise position and height control of the chip bonding, the top side (gate/source or anode pad side) of SiC power devices are flip-chip bonded to circuit electrodes using sub-micron Au particle with low temperature (250°C) and pressure-less sintering. The accuracy of the bonding position of chips was less than 10 μm and the accuracy of the height after bonding chips was less than 15 μm. Mechanical shear fatigue tests for flip-chip bonded SiC Schottky barrier diode (SBD) were carried out. As a result, initial shear strength of the joint was 36 MPa. The shear strength of 43 MPa is obtained after storage life test (500 hours at 250°C), and also 35 MPa is obtained even after thermal cycle stress test (1000 cycles between −40°C and 250°C). The flip-chip bonding of SiC-JFET is successfully realizedon the substrate without short or open failure electrically. Finally we joint the backside of the SiC-JFET (drain side) and the SiC-SBD (cathode side) to each circuit electrodes at once by means of reflow process with Au-12%Ge solder. The structured sandwich SiC power module was also successfully formed.

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Research and application of a high-performance fluorocarbon plate prepared via modified a high temperature mould pressing method

RSC Advances ◽

10.1039/d0ra06203k ◽

2020 ◽

Vol 10 (53) ◽

pp. 32265-32275

Author(s):

Pan Zhang ◽

Ye Wang ◽

Yi-rui Shu ◽

Yan-jun Zhong ◽

Wei Wang ◽

...

Keyword(s):

High Temperature ◽

High Performance ◽

High Density ◽

Pressing Method

Applications of high density carbon plates that are high-temperature pressed using material resistance.

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Stimulated Brillouin scattering behaviors in multi-ion species plasmas in high-temperature and high-density region

Physics of Plasmas ◽

10.1063/1.5088372 ◽

2019 ◽

Vol 26 (5) ◽

pp. 052101 ◽

Cited By ~ 4

Author(s):

Q. S. Feng ◽

C. Y. Zheng ◽

Z. J. Liu ◽

L. H. Cao ◽

Q. Wang ◽

...

Keyword(s):

High Temperature ◽

Brillouin Scattering ◽

Stimulated Brillouin Scattering ◽

High Density ◽

Density Region ◽

High Density Region ◽

Stimulated Brillouin ◽

Ion Species

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Reaction Mechanism and Process Control of Hydrogen Reduction of Ammonium Perrhenate

Metals ◽

10.3390/met10050640 ◽

2020 ◽

Vol 10 (5) ◽

pp. 640

Author(s):

Junjie Tang ◽

Yuan Sun ◽

Chunwei Zhang ◽

Long Wang ◽

Yizhou Zhou ◽

...

Keyword(s):

Particle Size ◽

High Temperature ◽

Particle Size Distribution ◽

Size Distribution ◽

Hydrogen Reduction ◽

Reduction Rate ◽

Reduction Reaction ◽

High Density ◽

Reduction Temperature ◽

Ammonium Perrhenate

The preparation of rhenium powder by a hydrogen reduction of ammonium perrhenate is the only industrial production method. However, due to the uneven particle size distribution and large particle size of rhenium powder, it is difficult to prepare high-density rhenium ingot. Moreover, the existing process requires a secondary high-temperature reduction and the deoxidization process is complex and requires a high-temperature resistance of the equipment. Attempting to tackle the difficulties, this paper described a novel process to improve the particle size distribution uniformity and reduce the particle size of rhenium powder, aiming to produce a high-density rhenium ingot, and ammonium perrhenate is completely reduced by hydrogen at a low temperature. When the particle size of the rhenium powder was 19.74 µm, the density of the pressed rhenium ingot was 20.106 g/cm3, which was close to the theoretical density of rhenium. In addition, the hydrogen reduction mechanism of ammonium perrhenate was investigated in this paper. The results showed that the disproportionation of ReO3 decreased the rate of the reduction reaction, and the XRD and XPS patterns showed that the increase in the reduction temperature was conducive to increasing the reduction reaction rate and reducing the influence of disproportionation on the reduction process. At the same reduction temperature, reducing the particle sizes of ammonium perrhenate was conducive to increasing the hydrogen reduction rate and reducing the influence of the disproportionation.

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