Analyzing Various Structural and Temperature Characteristics of Floating Gate Field Effect Transistors Applicable to Fine-Grain Logic-in-Memory Devices.

Although the von Neumann architecture-based computing system has been used for a long time, its limitations in data processing, energy consumption, etc. have led to research on various devices and circuit systems suitable for logic-in-memory (LiM) computing applications. In this paper, we analyze the temperature-dependent device and circuit characteristics of the floating gate field effect transistor (FGFET) source drain barrier (SDB) and FGFET central shallow barrier (CSB) identified in previous papers, and their applicability to LiM applications is specifically confirmed. These FGFETs have the advantage of being much more compatible with existing silicon-based complementary metal oxide semiconductor (CMOS) processes compared to devices using new materials such as ferroelectrics for LiM computing. Utilizing the 32 nm technology node, the leading-edge node where the planar metal oxide semiconductor field effect transistor structure is applied, FGFET devices were analyzed in TCAD, and an environment for analyzing circuits in HSPICE was established. To seamlessly connect FGFET-based devices and circuit analyses, compact models of FGFET-SDB and -CSBs were developed and applied to the design of ternary content-addressable memory (TCAM) and full adder (FA) circuits for LiM. In addition, depression and potential for application of FGFET devices to neural networks were analyzed. The temperature-dependent characteristics of the TCAM and FA circuits with FGFETs were analyzed as an indicator of energy and delay time, and the appropriate number of CSBs should be applied.

Thermodynamic Studies on the Hydrolysis of Trivalent Plutonium and Solubility of Pu(OH)3(am).

The temperature-dependent reaction properties of actinide elements are of particular interest in the safety assessment of high-level radioactive waste (HLRW) disposal systems. In this study, the hydrolysis of Pu(III) and the solubility of Pu(OH)3(am) were investigated at various temperatures (10-40 °C) in 0.1 M NaClO4. A strong reducing condition for maintaining the oxidation state of Pu(III) while slowly increasing the pH of the solution was realized by electrolysis. The formation constants of the first hydrolysis species, log *ß1', and the solubility products of Pu(OH)3(am), log *Ks,0', at 10, 17, and 40 °C were experimentally determined using spectrophotometry, laser-induced breakdown detection, and radiometry. The enthalpy and entropy changes for these reactions were estimated using the van't Hoff equation. The first hydrolysis of Pu(III) is endothermic (ΔrHm° = 34.10 ± 4.48 kJ mol-1), and the dissolution of Pu(OH)3(am) is exothermic (ΔrHm° = -294.29 ± 23.05 kJ mol-1) with negative entropy changes. These thermodynamic data will contribute to improving the reliability of the safety assessment of HLRW disposal facilities and understanding the geochemical behavior of Pu under reducing or anoxic aqueous conditions at elevated temperatures.

Effect of myocardial protection of intracoronary adenosine and nicorandil injection in patients undergoing non-urgent percutaneous coronary intervention: a randomized controlled trial.

BACKGROUND: Several studies have demonstrated that adenosine and nicorandil protect the myocardium against angioplasty-related myocardial injury. We conducted a prospective study to investigate the myocardial protective effects of combination therapy with intracoronary adenosine and nicorandil. METHODS: We enrolled 213 consecutive patients with stable or unstable angina who were scheduled for non-urgent PCI for de-novo coronary lesions. Patients were randomized into group I (control saline, n=55), group II (adenosine 50 µg, n=54), group III (nicorandil 4 mg, n=54), or group IV (adenosine-nicorandil combination, n=50). Serial assessments of CK-MB were used to assess myocardial necrosis before and after PCI. The primary endpoint was the incidence of myocardial necrosis (elevation of CK-MB), and the secondary endpoints were the changes in serum CK-MB and cTnI levels and the incidence of post-procedural myocardial infarction (MI). RESULTS: No significant differences were observed among the four groups with regard to baseline or angiographic characteristics. No major adverse events related to adenosine and nicorandil were observed. There were no significant differences in the incidence of post-procedural myocardial necrosis among the four groups (10.9, 14.8, 14.8, and 14.0%, respectively, p=0.9). There were no significant differences in the incidence of post-procedural MI among groups (p=0.6). In multivariate regression analysis, multivessel stenting, median stent length, and the presence of a compromised side branch were independent predictors of myonecrosis. CONCLUSIONS: Pretreatment with intracoronary adenosine, nicorandil, or the combination of the two drugs did not reduce the incidences of myocardial necrosis or MI after non-urgent PCI in patients with low-risk angina pectoris.