Temperature Ramp Research Articles

Experimental evaluation of barium bromide-ammonia equilibrium lines

This work has experimentally evaluated the position of thermochemical equilibrium lines of barium bromide (BaBr2) reacting with ammonia (NH3). BaBr2 samples, contained in discs of Expanded Natural Graphite, were placed in an experimental Large Temperature Jump rig and a new methodology, termed the Fast Temperature Ramp, was used to reveal adsorption and desorption reactions. Reaction onset points were plotted to generate equilibrium lines and calculate reaction enthalpies and entropies. Significant hysteresis between adsorption and desorption reactions was found, with the degree of hysteresis increasing as the salt becomes more deammoniated. The hysteresis effect was greatest for BaBr2(2–1) and BaBr2(1–0) reactions and also increased at higher pressures, exceeding 20 °C at 900 kPa for BaBr2(1–0). Adsorption reactions were found to occur over a very small temperature range, giving rise to a single transition ‘zone’ less than 20 °C wide. TGA experiments confirmed the position of equilibrium lines, although they were not successful in differentiating between two of the four ammoniated states. The close position of all equilibrium lines gives rise to a temperature ‘zone’ encompassing all four reactions, and in future work it may be advantageous to consider BaBr2 as a pseudo single-transition salt instead.

RF-Sputtered Ti-Based Dielectric Layers as Al-Diffusion Barrier for Passivating Contacts

We investigate TiNx layers deposited via RF magnetron sputtering on their efficacy as a diffusion barrier layer between Al and tunnel oxide passivated contact layer stacks during contact formation in a fast firing process. We obtain implied open-circuit voltage (iVOC) from photo-conductance decay measurements in order to analyse the diffusion barrier quality for different parameter variations. In particular, we show the impact of both higher peak temperature and increased thermal budget (by decreasing the slope of the temperature ramp) on iVoc during the sintering (“fast firing”) process, leading to passivation quality losses. iVOC losses below 1.5% are shown for peak firing temperatures up to 725°C, with absolute values up to 717 mV after firing. Contact formation at this temperature yields median contact resistivity (ρc) values below 3 mΩcm2 with a sheet resistance (Rsheet) of about 40 Ω/□ for the Ti-based layers.

Comparison of dU/dQ, Voltage Decay, and Float Currents via Temperature Ramps and Steps in Li‐ion Batteries

Comparison of dU/dQ, Voltage Decay, and Float Currents via Temperature Ramps and Steps in Li‐ion Batteries

Selective Epitaxial Growth of SiGe(:B) for Advanced p-Type Fd-SOI

Epitaxy is of major importance during the manufacturing of p-type metal oxide semiconductor field effect transistors (p-MOSFETs) for next generation fully depleted-silicon on insulator (FD-SOI) integrated circuits. A compressive-strained SiGe channel has indeed to be present in p-type regions for threshold voltage tuning and hole mobility boosting. In-situ boron-doped SiGe raised sources/drains (RSD) have otherwise to be used to reduce access resistance and, ideally, inject uniaxial compressive strain in the channel. Selective epitaxial growth (SEG) is needed for both types of layers,with deposition occurring solely in Si or SiGe areas surrounded by dielectrics. Reduced pressure-chemical vapor deposition (RP-CVD) processes in the 600–800 °C range have been under study for years. We are however still facing technical constraints during their use into complex process flows. Hence, optimizations are required to achieve suitable films in terms of Ge and B compositions (with sometimes dopant incorporation above their solubility limit), morphology (significantly thicker layers in small patterns) and structure (faceting and anisotropic effects). We focus here on various SEG processes used during the manufacturing of advanced p-MOSFET devices, as depicted in Fig. 1: (i) 20 nm thick in-situ boron doped Si0.7Ge0.3 layers grown at 650 °C, 20 Torr then capped with 5 nm of Si:B (at 730 °C, 20 Torr) for RSDs and (ii) 8 nm intrinsic SiGe layer grown at 650–700 °C, 20 Torr for channels. For each process, growth rate, layer composition and selectivity (e.g. poly-nuclei density) were first assessed through depositions on 300 mm bare Si (001) substrates or wafers fully covered by dielectrics (SiO2 or Si3N4). Subsequently, optimal blanket conditions were evaluated on test-patterned substrates then tailored for a use during electrical device fabrication.First of all, the Si0.7Ge0.3:B growth kinetics and doping was evaluated at 650 °C, 20 Torr with a SiH2Cl2 + GeH4 + HCl + B2H6 + H2 chemistry. As expected, we had a linear increase of the SiGe:B growth rate with the B2H6 partial pressure (Fig. 2(a)). This was due to a catalysis of H desorption on B surface sites. Selectivity was initially assessed on oxide surfaces to determine the appropriate amounts of B2H6 and HCl for given SiH2Cl2 and GeH4 mass-flows. As shown in Fig. 2(b), two different B2H6 partial pressures, 0.03 and 0.11 mTorr, resulted in a lack and the presence of poly-nuclei on SiO2 surfaces, respectively. “Apparent” and atomic Ge contents, from high resolution X-ray diffraction (HRXRD) and X-ray fluorescence (XRF) measurements, are plotted as functions of the B2H6 partial pressure in Fig. 2(c). The difference between the two gave us access to the substitutional B concentrations, which will soon be compared with atomic and possibly electrically active B concentrations (from SIMS and Hall effect measurements).Given the challenges associated with the formation of germano-salicides with the right properties, we have also evaluated the growth of a Si:B cap on SiGe:B. Various process parameters at 730 °C and 20 Torr were examined in order to have selectivity, thanks to the proper F(SiH2Cl2)/F(HCl) mass-flow ratio, and a meaningful growth rate (addition of B2H6). Active temperature ramps were adopted to prevent elastic relaxation and thus the formation of undulated SiGe:B surfaces. The growth rates (Fig. 3(a)) and structural quality (Fig. 3(b)) of {SiGe:B/Si:B} stacks were assessed with XRD for different Si:B cap thicknesses.SEG of {SiGe:B/Si:B cap} was then used to thicken the SD regions on each side of FD-SOI pMOSFETs. The right thicknesses, a high crystalline quality and a smooth SiGe:B/Si:B interface were obtained, as shown by Fig. 4 TEM cross-section. Challenges faced during the integration of such a SEG process will be discussed, including the selection of the right surface preparation strategy on SiGe channels, faceting and loading effects.Finally, SiGe 20%–30% SEG followed by high temperature oxidation is used to fabricate the SiGe channels of SOI devices. To that end, SEG must be strictly controlled. A blanket study was therefore performed at 20 Torr with SiH2Cl2, GeH4 and HCl. Three temperatures (650, 675 and 700 °C) were evaluated in terms of intrinsic SiGe growth rate, Ge content (Fig.5 (a)) and selectivity versus SiN surfaces. We had at 700 °C a severe layer corrugation and islanding for 8 nm of SiGe grown on patterned SOI wafers, as shown by Fig. 5(b) SEM images. Reducing the growth temperature minimized the surface roughness, with definitely longer growth durations as growth rates were smaller, then. When switching to real patterned devices, a combination of in-line monitoring techniques will be mandatory to properly determine the thickness and Ge content of such thin SiGe channels. Figure 1

A practical analysis to predict sample overheating in flash experiments using the current ramp methodology

AbstractThis work presents a straightforward strategy for achieving specific overheating during flash experiments by adjusting the initial electrical parameters. To do that, an extensive experimental analysis was performed to evaluate the temperature evolution of dense ZnO specimens during controlled‐current ramping at different furnace temperatures, which in turn modified the initial electrical resistance of the sample. A detailed electrical explanation of controlled‐current ramp flash processes is provided and, for the first time, a practical equivalence between current‐ramp and temperature‐ramp flash methodologies is established. By parameterizing the experiments in terms of an effective power density, a consistent heating pattern following the blackbody radiation trend was identified, despite the different electrical characteristics of each experiment. Finally, a “flash heating map” is introduced, which can be used to determine the starting electrical parameters necessary to achieve a specific temperature increase, whether employing current or temperature ramps.

A Robust Low‐Power Power‐On‐Reset Circuit With Dual Threshold Method

ABSTRACTIn this paper, a robust low‐power power‐on‐reset (POR) circuit with dual threshold method is proposed. The current‐based circuit exhibits good robustness with respect to process, voltage, temperature, and supply ramp variations. In contrast to conventional delay‐based pulse generation approaches, a dual threshold method is introduced to generate POR and brown‐out‐reset (BOR) pulse signals, resulting in ultralow quiescent current and a compact area. Implemented in the 55‐nm CMOS process, the proposed circuit achieves an accurate trigger‐point voltage with a temperature coefficient of 90.4 ppm/°C and a deviation to the ramp time of 2.9% for a range from 100 μs to 1 s. Furthermore, the quiescent current and active area are 0.3 nA and 4834 μm2, respectively, making it particularly suitable for energy harvesting systems.

Evaluation of Kinetic and Thermodynamic Parameters of Pyrolysis and Combustion Processes for Bamboo Using Thermogravimetric Analysis

As a typical forestry waste, bamboo has gained increasing attention for its potential applications. In order to optimize its valorization, understanding the kinetic and thermodynamic parameters of bamboo pyrolysis and combustion is crucial. In this study, thermogravimetric analysis (TGA) was employed to examine bamboo powder’s pyrolysis and combustion behaviors under different temperature ramps in nitrogen and air environments, and the kinetic and thermodynamic parameters were evaluated using the Flynn–Wall–Ozawa (FWO), Kissinger–Akahira–Sunose (KAS), and Starink (STR) model-free approaches. The main findings are as follows. (1) The thermogravimetry (TG) and derivative thermogravimetry (DTG) (DTG) curves reveal that bamboo pyrolysis occurs in three distinct stages: drying, devolatilization, and carbonization. Similarly, combustion also proceeds through three stages: drying, devolatilization, and char combustion. Notable differences in the temperature ranges of the key stages were observed between pyrolysis and combustion. (2) The activation energies during the oxidative devolatilization stage of combustion are notably lower compared to those during pyrolysis devolatilization. The disparity in activation energy is even more pronounced in the third stage. (3) Thermodynamic analysis shows that the pyrolysis and combustion of bamboo are endothermic and non-spontaneous. It can be stably converted into value-added energy through the pyrolysis or combustion process. This study provides essential data to aid in designing and scaling up the thermochemical conversion processes for bamboo and promote its efficient valorization of bioenergy.

Intraspecific variation in rapid cold hardening and acclimation of the adventive parrot’s feather weevil, Phytobius (=Parenthis) vestitus, in the southern USA

Plasticity in thermal tolerance, expressed through acclimation or rapid cold hardening, for example, provides organisms with a mechanism to deal with unexpected and often rapid changes in the thermal environment. Spatial variation in response to high or low temperatures may occur due to evolutionary adaptation, particularly if a fitness increase coincides with the ability to respond quickly to environmental change. Thermal tolerances of beneficial insects used for biological control dictate where and under what thermal conditions the insects will provide value to management programs. We investigated two aspects of thermal phenotypic plasticity in response to thermal conditions using four populations of the adventive parrot’s feather weevil, Phytobius vestitus, from the southern USA. At low temperatures, we determined the presence and variation in rapid cold hardening in one of the four populations using two temperature ramping rates. In contrast, at high temperatures, all P. vestitus populations displayed a significant heat acclimation response, documented as elevated loss of motor control and motor function temperatures after acclimation. Thus, observed patterns of plasticity differed between high and low temperatures and among source populations. These results demonstrate the presence of geographic variation in phenotypic plasticity in response to thermal environments and emphasizes the need to consider plasticity when selecting climate-adapted populations of biological control agents.

The role of irradiation-enhanced interstitial diffusion in over-pressurizing fission gas bubbles in UO2

Fission gas bubbles in UO2 nuclear fuel have been observed to exhibit pressures in excess of the equilibrium bubble pressure; however, the cause of bubble over-pressurization has not yet been demonstrated. The mechanical interaction between a bubble and the surrounding matrix or grain boundary depends on the internal pressure of the bubble and local stress state, such that over-pressurized bubbles are thought to be responsible for fragmentation and pulverization, when exposed to a temperature ramp. Here, we investigate the role of U interstitials, produced through irradiation, in over-pressurizing bubbles by using a combined molecular dynamics (MD) and cluster dynamics approach. Firstly, the energies for the capture of interstitials and vacancies by bubbles have been determined from MD as a function of the ratio of gas atoms to vacancies that make up the bubble. Secondly, these reaction energies have been implemented in the cluster dynamics code Centipede to predict bubble over-pressurization as a function of temperature for typical fission rates. It was found that there is a transition from low pressure bubbles (at high temperatures) to high pressure bubbles (at lower temperatures). The cause of this behavior was shown to be the creation of irradiation-induced interstitials that are highly mobile relative to vacancies at low temperature; whereas, vacancies are sufficiently mobile at high temperatures to limit bubble pressures. This result supports the hypothesis that over-pressurized bubbles form during steady-state operation and that this behavior is highly sensitive to the local pellet temperature.

Development and validation of an ICP-MS method and its application in assessing heavy metals in whole blood samples among occupationally exposed lead smelting plant workers.

Occupational exposure to heavy metals affects various organ systems and poses a significant health risk to workers. Consequently, its precise estimation is of clinical concern and warrants the need for an analytical method with reliable precision and accuracy. The current study aimed to develop an analytical method using inductively coupled plasma‒mass spectrometry (ICP-MS) to detect trace to elevated levels of potentially toxic elements in human blood. The sample preparation was optimized using a two-step ramp temperature microwave acid digestion program. The toxic elements were quantified using ICP-MS operating in kinetic energy discrimination (KED) mode, adjusting the data acquisition parameters and instrumental settings. The analytical method was validated using standard performance parameters. Each validation parameter was aligned with the acceptable criteria outlined in standard guidelines. The method achieved optimal linearity (r2 > 0.99), recovery (85.60-112.00%), and precision (1.35-7.03%), was capable of detecting the lowest concentrations of 0.32, 0.28, 0.28, and 0.19µg/L, and was capable of quantifying trace levels of 1.01, 0.88, 0.90, and 0.62µg/L for arsenic (As), cadmium (Cd), mercury (Hg), and lead (Pb), respectively. Post-validation, the method was applied to estimate heavy metals in blood samples from 250 Pb-smelting plant workers, revealing potential health implications of occupational exposure. The cohort analysis revealed that demographic and employment factors were associated with elevated blood Pb levels, leading to symptoms and health risks. Clinical analysis revealed that 33.6% of the participants experienced hypertension. These findings highlight the significant health risks associated with elevated blood Pb levels. The weak but significant correlation with systolic blood pressure underscores the need for improved monitoring and workplace safety. This emphasizes the importance of continuous monitoring, targeted interventions, and enhanced occupational hygiene to protect workers' well-being.

Accelerating float current measurement with temperature ramps revealing entropy insights

This research examines the behavior of three types of lithium-ion cells during a voltage hold, precisely measuring the necessary float current IFloat during stepwise changes and temperature ramps from 5 to 50 °C to increase data acquisition rate and speed compared to stepwise approaches. The float current is thereby associated with calendar aging and superimposed by entropy effects in case of temperature ramps. By combining upward and downward ramps and different ramp speeds, the shares of entropy and aging can be separated. Thereby, the entropy-induced current IE across all tested cells is not constant but increases linearly with temperature. This linearity, coupled with direct proportionality between IE and the temperature ramp speed, underscores the predictability of the entropy effect in these cells under varying temperature conditions. With the knowledge of the entropy current, the aging current IAging can be derived from temperature ramps and is compared with the state-of-the-art measurements during temperature steps, employing two evaluation methods. While 9 out of 12 cells show high agreement. Significant discrepancies are observed at lower voltages, particularly for high capacity NMC/NCA-cells. Kinetic effects and measurement limitations at low aging currents are expected to be the root cause, especially for upward ramps starting from cold temperatures.

End Column Reverse Chromatography as a Novel Approach for Enhanced Separation: A Pilot Study.

Currently, the most popular technique in gas chromatography (GC) is the "temperature programming", where the temperature increases from the start of the injection. This leads to faster elution of analytes compared to isothermal methods. However, isothermal methods are considered optimal for separating compounds with similar retention times. Another interesting technique that provides higher resolution is the dynamic thermal gradient gas chromatography (TGGC), where separations are achieved as a decreasing thermal gradient. This gradually decreases the positive gas velocity. Nevertheless, it was proven that GC techniques with negative velocity gradients don't improve the resolution of compounds with nearly identical retention times. Optimizing a new GC approach to combine both the short time from positive temperature ramps programming, and the enhanced separation of the negative ramps of the TGGC, a model under the name of "end column reverse chromatography". The process simply consists of two steps, the first is a normal positive ramp from the start of the injection, the second step is a negative thermal ramp at a time that is around the retention time of the first eluting peak. This will decrease the solute velocity almost solely for the second compound leading to relatively enhanced separation. Optimized ECRC method increased the resolution of two isomers (trans and cis chlordane) from 1 (slightly overlapping) in case of temperature programming to 2.78 as shown in this study. This comes in expense of the width and intensity of the peaks, where the intensity decreased about 17% and 12% for cis and trans chlordane, and the peak width increased with 37% and 77% for the same compounds respectively. ECRC is a novel model for enhanced separation that comes with some drawbacks. It can be an alternative approach to get a fast GC method with enhanced separation for isomers.

Does H2 Temperature‐Programmed Reduction Always Probe Solid‐State Redox Chemistry? The Case of Pt/CeO2

Redox reactions on the surface of transition metal oxides are of broad interest in thermo, photo, and electrocatalysis. H2 temperature‐programmed reduction (H2‐TPR) is commonly used to probe oxide reducibility by measuring the rate of H2 consumption during temperature ramps, assuming that this rate is controlled by oxide reduction. However, oxide reduction involves several elementary steps, such as H2 dissociation and H‐spillover, before surface reduction and H2O formation occur. In this study, we evaluated the kinetics of H2 consumption over CeO2 and Pt/CeO2 with varying Pt loadings and structures to identify the elementary steps probed by H2‐TPR. Literature often attributes changes in H2‐TPR characteristics with Pt addition to increased CeO2 reducibility. However, our analysis revealed that the H2 consumption rate is measurement of the rate of H‐spillover at Pt‐CeO2 interfaces and is determined by the concentration of Pt species on Pt nanoclusters that dissociate H2. Therefore, lower temperature H2 consumption observed with Pt addition does not indicate higher CeO2 reducibility. Measurements on samples with mixtures of Pt single‐atoms and nanoclusters demonstrated that H2‐TPR can effectively quantify dilute Pt nanocluster concentrations, suggesting caution in directly linking H2‐TPR characteristics to oxide reducibility while highlighting alternative material insights that can be gleaned.

Does H2 Temperature-Programmed Reduction Always Probe Solid-State Redox Chemistry? The Case of Pt/CeO2.

Redox reactions on the surface of transition metal oxides are of broad interest in thermo, photo, and electrocatalysis. H2 temperature-programmed reduction (H2-TPR) is commonly used to probe oxide reducibility by measuring the rate of H2 consumption during temperature ramps, assuming that this rate is controlled by oxide reduction. However, oxide reduction involves several elementary steps, such as H2 dissociation and H-spillover, before surface reduction and H2O formation occur. In this study, we evaluated the kinetics of H2 consumption over CeO2 and Pt/CeO2 with varying Pt loadings and structures to identify the elementary steps probed by H2-TPR. Literature often attributes changes in H2-TPR characteristics with Pt addition to increased CeO2 reducibility. However, our analysis revealed that the H2 consumption rate is measurement of the rate of H-spillover at Pt-CeO2 interfaces and is determined by the concentration of Pt species on Pt nanoclusters that dissociate H2. Therefore, lower temperature H2 consumption observed with Pt addition does not indicate higher CeO2 reducibility. Measurements on samples with mixtures of Pt single-atoms and nanoclusters demonstrated that H2-TPR can effectively quantify dilute Pt nanocluster concentrations, suggesting caution in directly linking H2-TPR characteristics to oxide reducibility while highlighting alternative material insights that can be gleaned.

Effect of particle stiffness on microgel self-assembly and suspension phase behavior over a broad temperature range

We synthesized thermoresponsive poly(N-isopropylacrylamide) (PNIPAM) colloidal microgel particles of different stiffnesses by controlling the concentration of a polar crosslinker in a precipitation polymerization synthesis method. When suspended in an aqueous medium, the particles collapsed by expelling water as the temperature was raised toward the volume phase transition temperature (VPTT) of ≈ 34 °C. We noted that the sizes of the stiffer particles, synthesized with higher crosslinker concentration, collapsed less abruptly. Using Fourier transform infrared spectroscopy, we observed enhanced particle dehydration with increasing temperature and decreasing particle stiffness. Oscillatory rheology experiments on dense aqueous PNIPAM suspensions, prepared at a fixed particle effective volume fraction ϕeff = 1.5 at 25°C, revealed that suspensions constituted by the stiffest particles are the most elastic over a broad temperature range. Above the VPTT, suspensions of particles of intermediate stiffnesses exhibited two-step yielding, a typical signature of fragile gel formation. Zeta potential measurements showed that PNIPAM particles of lower stiffnesses are rendered electrostatically unstable in aqueous suspension. Combining cryogenic scanning electron microscopy and rheology, we noted a glass–glass transition when the temperature of a dense suspension of stiff PNIPAM particles was raised across the VPTT. In contrast, suspensions of particles of the lowest stiffnesses showed a gel-viscoelastic liquid–gel transition during an identical temperature ramp experiment. Our study reveals that temperature-induced phase transformations in dense PNIPAM suspensions depend sensitively on the stiffness of the constituent particles and can be explained by considering amphiphilicity-driven morphological changes in the suspension microstructures.

Thermomechanical and Viscoelastic Characterization of Continuous GF/PETG Tape for Extreme Environment Applications

The thermomechanical and viscoelastic properties of a glass fiber polyethylene terephthalate glycol (GF/PETG) continuous unidirectional (UD) tape were investigated using differential scanning calorimetry (DSC), thermomechanical analysis (TMA), and dynamic mechanical analysis (DMA). This study identified five operational conditions based on the Army Regulation 70-38 Standard. The DSC results revealed a glass transition temperature of 78.0 ± 0.3 °C, guiding the selection of temperatures for TMA and DMA tests. TMA provided the coefficient of thermal expansion in three principal directions, consistent with known values for PETG and GF materials. DMA tests, including strain sweep, temperature ramp, frequency sweep, creep, and stress relaxation, defined the material’s linear viscoelastic region and temperature-dependent properties. The frequency sweep indicated an increased modulus with rising frequency, identifying several natural frequency modes. Creep and stress relaxation tests showed time-dependent behavior, with strain increasing under higher loads and stress decreasing over time for all tested input values. Viscoelastic models fitted to the data yielded R2 values of 0.99, demonstrating good agreement. The study successfully measured thermomechanical and viscoelastic properties across various conditions, providing insights into how temperature influences the material’s mechanical response under extreme conditions.

Carbon nanotube manipulates crystallization kinetics and viscoelastic behavior of PP/EBC blends

AbstractPolypropylene (PP) offers numerous benefits to industrial applications due to its excellent processability and cost‐effectiveness. However, the widespread utilization of this commodity thermoplastic is constrained by its inherently low‐impact resistance. Herein, we suggest a ternary system with the addition of ethylene‐butene copolymer (EBC) and multiwalled carbon nanotubes (MWCNTs) to improve the overall performance of PP. We unveil the role of MWCNTs on the crystalline behavior of the PP/EBC blends when various ratios are considered. The calculated half‐time crystallization from the Avrami equation indicates that 1.5 wt% MWCNTs accelerate the crystallization of the PP/EBC blend nearly threefold. The formation of a semisolid microstructure is also reported using the rheological measurements. An upturn in complex viscosity, along with a frequency‐independent storage modulus, indicates strong interactions between MWCNTs and polymer chains. We confirm such robust interactions by employing temperature ramp sweep on the prepared nanocomposites as the decomposition temperature of the materials shifts to higher values. The dynamic mechanical analysis further interprets the role of MWCNTs as compatibilizers by bridging the gap between the glassy temperature of PP and EBC components.Highlights Theoretical prediction of the MWCNTs localization in the PP/EBC blends. Depicting the solid‐like behavior and viscosity upturn of PP/EBC/MWCNTs. Decelerating polymer chain relaxation led by nucleation role of MWCNTs. Formation of larger and more imperfect crystals upon the addition of MWCNTs. Faster crystallization kinetics in the PP/EBC/MWCNTs nanocomposites.

Advanced SiGe:B Raised Sources and Drains for p-type FD-SOI MOSFETs

We have evaluated the feasability of selectively growing, with a chlorinated chemistry, 20 to 30 nm thick SiGe:B Raised Sources and Drains with Ge concentration gradients (from 50% down to 20%-30%, typically) on each side of FD-SOI transistors. The motivation was twofold: (i) inject meaningful amounts of compressive strain in the channel of p-type MOS devices thanks to high Ge concentrations in layers sitting in the same plane than Si or SiGe channels and (ii) benefit from lower Ge concentration SiGe layers on top that are easier to germano-silicide. Growing a thin Si(:B) cap on SiGe:B otherwise yields more uniform and stable contacts. We have thus studied the Si capping of SiGe 20% or 30% layers. As growth has to be conducted, for Si, at temperatures significantly higher than that of SiGe (750°C, to be compared with 700°C for SiGe 20% and 650°C for SiGe 30%, typically), we have quantified the impact of using temperature ramping-ups with SiH2Cl2 + HCl flowing into the growing chamber. The purpose of such active ramps was to prevent elastic strain relaxation, e.g. the formation of SiGe surface undulations that would happen with temperature ramps under H2 only.

A custom-made integrated system for thermoluminescence and radioluminescence spectroscopy

Thermoluminescence (TL) and Radioluminescence (RL) are widely used in dosimetry applications. We present a custom-built integrated system, designated LUMI22, for measuring TL, TL spectroscopy, RL, and RL as a function of temperature. LUMI22 includes a heating system based on Kanthal® A1 alloy (FeCrAl), a microcontroller to regulate the temperature ramps (e.g. 1–5 °C/s). To irradiate samples an X-ray tube (Moxtek 50 kV, 50 μA) is powered, controlled, and monitored by an FTC-200 standard controller. The dose rate at the sample position is 0.43 Gy/min. Light collection includes a Photomultiplier Tube (PMT, Hamamatsu H10493-012:HA, 185–850 nm). Additionally, a miniature fiber optic spectrometer (Ocean Optics, QE65000, range 200–1100 nm) coupled with a 1000 μm diameter fiber optic (QP1000- 2-UV-VIS) was employed for TL and RL spectroscopy measurements. To assess the functionality of the system, it was used to measure TL and RL from Al2O3:C,Mg, Al2O3:C and TLD-100 phosphors which have been previously well investigated. The measured TL and RL data were well compared to the published ones, confirming the functionality of the system.

Detection of PCBs and OCPs in the Irtysh River Water (GC-MS/MS) and ecological risk assessment

This study optimized a gas chromatography-tandem triple quadrupole mass spectrometry (GC-MS/MS) method for the determination of 21 persistent organic pollutants (POPs) in Irtysh River water, including 14 organochlorines (OCPs) and 7 polychlorinated biphenyls (PCBs). Factors such as column temperature ramping, selection of qualitative and quantitative ion pairs and collision energy were considered to achieve perfect separation and accurate quantification of all 21 target compounds. The limits of detection (LOD) for PCBs and OCPs ranged from 0.21 to 1.18 ng/L. Applying this method to detect POPs in the Irtysh River revealed concentrations of OCPs ranging from ND to 20.2 ng/L and PCBs from ND to 0.411 ng/L. Source analysis indicated that POPs in the Irtysh River mainly originate from historical industrial and agricultural activities, particularly the deliberate use of pesticides. To ensure ecological safety and human health, expanding the range of target analytes and monitoring periods is necessary. This study provides:•Qualitative and quantitative analysis methods for 7 PCBs and 14 OCPs.•Recoveries achieved ranged between 74.6 to 109 % with RSD less than 15 %.•Analysis of sources, transport pathways, accumulation status, and ecological risks of PCBs and OCPs in the Irtysh River.