Your search keyword '"in-situ measurements"' showing total 86 results

1. Effects of strain rate on martensitic phase transformation in TRIP assisted multiphase steels studied in-situ with X-ray diffraction

Author

Langi, Veera, Pun, Lalit, Ruiz, Arturo Rubio, Isakov, Matti, and Hokka, Mikko

Published

2025

2. A drill hole in-situ lithium content measurement method based on pulsed neutron technology

Author

Liu, Chi, Zhang, Yan, Zhang, Haoran, Yu, Zihong, Li, Zhenrong, Zhong, Chonggui, He, Dexiong, Hu, Wenxing, Yu, Ziyan, Fang, Yuanyang, Wang, Renbo, and Tang, Bin

Published

2025

3. Record high counting rate of positron annihilation lifetime spectrometer achieved by [formula omitted] coincidence

Author

Xu, W., Li, Y.H., Luo, M., Liu, J.D., Ye, B.J., and Zhang, H.J.

Published

2025

4. Influence of Boundary Conditions on the Estimation of Thermal Properties in Insulated Building Walls.

Author

Rendu, Manon, Le Dréau, Jérôme, Salagnac, Patrick, and Doya, Maxime

Subjects

HEAT transfer coefficient, HEAT convection, HEAT capacity, HEAT transfer, THERMAL properties

Abstract

The objective of this study is to evaluate the ability of inverse techniques to estimate the resistance and the capacity of a highly insulated multilayer wall under real weather conditions. The wall is equipped with temperature sensors inside and on its inner and outer surfaces, and the boundary conditions have been measured over a 14-day period. Uncertainties on various parameters of the model are evaluated, including internal and external convective heat transfer coefficients (±20% and ±7 W.m-².K−1 respectively), external long-wave heat transfer coefficient (±0.15 W.m−2.K−1) and solar absorption coefficient (±0.06). A sensitivity analysis demonstrated the high correlation with some parameters defining the thermal performance of the walls (thermal resistance or capacity). A solution is proposed to limit the number of identified parameters, while allowing the identification of the thermal resistance and the thermal capacity of the walls. There are two cases: either the weather conditions are accurately measured (temperature, short- and long-wave radiation) and the thermal characteristics can be assessed, or intrusive sensors are installed, and the thermal characteristics can be evaluated more accurately. [ABSTRACT FROM AUTHOR]

Published

2024

5. Exponential distribution of wave-driven near-bed water speeds under short-crested waves: a case study in the eastern Gulf of Riga, the Baltic Sea

Author

Maris Eelsalu, Laura Piho, Juris Aigars, Loreta Kelpšaitė-Rimkienė, Vitalijus Kondrat, Maarja Kruusmaa, Kevin E. Parnell, Asko Ristolainen, Ilona Šakurova, Māris Skudra, Maija Viška, and Tarmo Soomere

Subjects

wave loads, wave climate, near-bottom velocity, water speed, hydromast, in-situ measurements, adv, weibull distribution, Science

Abstract

Loads exerted to the seabed by short-crested wind-seas with a wide directional spread have extensive spatio-temporal variability. We quantify this variability in terms of near-bed water speed using an array of nine high-resolution hydromast devices for recording pressure and water velocity in the range of 0.12â1 m/s mounted at a distance of 10 m from each other on a rigid rectangular frame of 20 Ã 20 m in approximately 4 m deep water and 700 m from the eastern shore of the Gulf of Riga near Skulte (Latvia) in AugustâSeptember 2022. This array is complemented by an acoustic Doppler velocimeter (ADV). The average background current is very weak, approximately 0.003 m/s in the measurement location. The empirical distributions of velocity components are symmetric but greatly deviate from the expected Gaussian distribution. The empirical distributions of water speeds follow an exponential distribution rather than a Rayleigh or Forristall distribution. This shape of the distributions appears in the range of 0.2â0.7 m/s while the maximum speed reaches 1.22 m/s. The rate parameter (inverse scale parameter) varies almost by a factor of two in recordings by different devices. The recordings make it possible to identify wakes of vessels entering to or departing from the Port of Skulte.

Published

2025

6. Radiated Sound and Transmitted Vibration Following the Ball/Racket Impact of a Tennis Serve

Author

Arthur Paté, Maxime Petel, Nesrine Belhassen, and Delphine Chadefaux

Subjects

tennis, sound, acoustic, vibration, in-situ measurements, sport, Physics, QC1-999

Abstract

Shock-induced vibrations transmitted from the racket to the tennis player’s upper limb have interested researchers, whether for investigating their effect on injury risk, or for designing new equipment. Measuring these vibrations is, however, very challenging in an ecological playing situation: sensors must be of very high quality in order to precisely measure high-energy and broad-frequency signals, as well as non-invasive in order to allow the players to perform their usual movements. The working hypothesis of this paper is that contactless sound recordings of the ball/racket impact carry the same information as direct vibratory measurements. The present study focuses on the tennis serve, as being tennis’ most energy-demanding stroke, therefore possibly being the most traumatic stroke for the upper limb. This article aims (a) to evaluate the propagation of vibration from the racket to the upper limb; and (b) to identify correlations with acoustic signals collected simultaneously. Eight expert tennis players performed serves with three rackets and two ball spin effects. Accelerometers measured the vibration on the racket and at five locations on the upper limb, and a microphone measured the impact sound. Resulting signals were analyzed in terms of energy and spectral descriptors. Results showed that flat serves produced louder sounds, higher vibration levels, lower acoustic spectral centroids, and higher vibratory spectral centroids than kick serves. The racket only had a marginal influence. Similarities between acoustic and vibratory measurements were found (levels were correlated), but so were differences (spectral centroids tended to be negatively correlated), encouraging further studies on the link between sound and vibration for the in situ measurement of shock-induced vibration.

Published

2024

7. Advanced Methods for Analyzing in-Situ Observations of Magnetic Reconnection.

Author

Hasegawa, H., Argall, M. R., Aunai, N., Bandyopadhyay, R., Bessho, N., Cohen, I. J., Denton, R. E., Dorelli, J. C., Egedal, J., Fuselier, S. A., Garnier, P., Génot, V., Graham, D. B., Hwang, K. J., Khotyaintsev, Y. V., Korovinskiy, D. B., Lavraud, B., Lenouvel, Q., Li, T. C., and Liu, Y.-H.

Subjects

*MAGNETIC reconnection, *ELECTROMAGNETIC fields, *MAGNETIC measurements, *MAGNETOSPHERE, *SOLAR system

Abstract

There is ample evidence for magnetic reconnection in the solar system, but it is a nontrivial task to visualize, to determine the proper approaches and frames to study, and in turn to elucidate the physical processes at work in reconnection regions from in-situ measurements of plasma particles and electromagnetic fields. Here an overview is given of a variety of single- and multi-spacecraft data analysis techniques that are key to revealing the context of in-situ observations of magnetic reconnection in space and for detecting and analyzing the diffusion regions where ions and/or electrons are demagnetized. We focus on recent advances in the era of the Magnetospheric Multiscale mission, which has made electron-scale, multi-point measurements of magnetic reconnection in and around Earth's magnetosphere. [ABSTRACT FROM AUTHOR]

Published

2024

8. Monitoring slow-moving deep-seated landslide using PSI technique: a case study of a potential sliding slope from southern Taiwan

Author

Lakhote, Abhishek, Chan, Yu-Chang, Lu, Chiao-Yin, Kumar, Gopal, and Sun, Cheng-Wei

Published

2025

9. Which and how many soil sensors are ideal to predict key soil properties: A case study with seven sensors

Author

J. Schmidinger, V. Barkov, H. Tavakoli, J. Correa, M. Ostermann, M. Atzmueller, R. Gebbers, and S. Vogel

Subjects

Proximal soil sensing, Remote sensing, Sensor fusion, Machine learning, Precision agriculture, In-situ measurements, Science

Abstract

Soil sensing enables rapid and cost-effective soil analysis. However, a single sensor often does not generate enough information to reliably predict a wide range of soil properties. Within a case-study, our objective was to identify how many and which combinations of soil sensors prove to be suitable for high-resolution soil mapping. On a subplot of an agricultural field showing a high spatial soil variability, six in-situ proximal soil sensors (PSSs) next to remote sensing (RS) data from Sentinel-2 were evaluated based on their capabilities to predict a set of soil properties including: soil organic carbon, pH, moisture as well as plant-available phosphorus, magnesium and potassium. The set of PSSs consisted of ion-selective pH electrodes, a capacitive soil moisture sensor, an apparent soil electrical conductivity measuring system as well as passive gamma-ray-, X-ray fluorescence- and near-infrared spectroscopy. All possible combinations of sensors were exhaustively evaluated and ranked based on their prediction performances using model stacking. Over all soil properties, data fusion demonstrated a considerable increase in prediction accuracy. Five out of six soil properties were predicted with an R2 ≥ 0.80 with the best sensor fusion model. Nonetheless, the improvement derived from fusing an increasing number of PSSs was subject to diminishing returns. Sometimes adding more PSSs even decreased prediction performances. Gamma-ray spectroscopy and near-infrared spectroscopy demonstrated to be most effective, both as single sensors or in combination with other sensors. As a single sensor, RS outperformed three out of six PSSs. RS showed especially potential for fusion with single PSSs but was of limited benefit when multiple PSSs were fused. Model stacking proved to be more robust than using single base-models because sensor performances were less model-dependent.

Published

2024

10. Variability and distribution of nighttime equatorial to mid latitude ionospheric irregularities and vertical plasma drift observed by FORMOSAT-5 Advanced Ionospheric Probe in-situ measurements from 2017 – 2020.

Author

Chang, Loren C., Hsieh, Yueh-Chun, Chao, Chi-Kuang, Duann, Yi, Salinas, Cornelius Csar Jude H., Liu, Jann-Yenq, and Lin, Charles C.H.

Subjects

*EQUATORIAL ionization anomaly, *IONOSPHERIC disturbances, *LATITUDE, *PLASMA sheaths, *IONOSPHERIC techniques, *ATMOSPHERIC tides, *IONOSPHERIC plasma

Abstract

Irregularities in ionospheric plasma distribution can result in severe scintillation and disruption to the radio frequencies utilized for satellite communications and navigation. In the low and mid latitudes, these irregularities can include Equatorial Plasma Bubbles (EPBs) and Travelling Ionospheric Disturbances (TIDs). EPBs are irregularities manifesting in low latitude nighttime ionosphere plasma density that can extend along magnetic field lines with zonal scales on the order of 100 km or less, while TIDs are propagating wave disturbances. High frequency in-situ measurements of ionospheric plasma aboard spacecraft in Low Earth Orbit (LEO) are a direct measurement of irregularities in plasma density and are therefore valuable for resolving EPB and TID occurrences, variability, and relation to other ionospheric parameters that are believed to play a driving role in the formation of such irregularities. In this study, we utilize observations taken over a three-year period between 2017 and 2020 by the Advanced Ionospheric Probe (AIP) carried aboard the FORMOSAT-5 satellite to examine the spatial, seasonal, and interannual variability of equatorial to mid latitude ionospheric irregularities and vertical ion drift during this time. AIP provides in-situ measurements of ion density and vertical ion drift in the equatorial to mid latitude ionosphere at approximately 720 km altitude with local times between 22:00 – 23:00 local time. Our global scale results resolve distinct and inter-annually recurrent seasonal patterns in the distribution of nighttime ionospheric irregularities and vertical plasma drift during this time. Elevated occurrences of ion density irregularities are resolved along the Equatorial Ionization Anomaly (EIA) latitudes, while notable occurrences with variability consistent with EPBs also observed along the low and equatorial magnetic latitudes. Zonal variability of equatorial irregularities consistent with the signatures of nonmigrating atmospheric tides are observed. It is also notable that the occurrences and geographic distribution of ion density irregularities showed a considerable level of interannual variability, especially at mid latitudes over the South Atlantic and Southern African sectors, which showed much higher levels of irregularities in 2017–––2018, compared to 2019 and 2020. In comparison, the spatial and interannual variation of the co-located vertical ion drifts were much more consistent during the years examined, indicating that the driver for the observed interannual variability in ion density irregularities cannot be attributed to the vertical ion drift at the same time and location of the observations. This highlights the need for in-situ instruments distributed across multiple satellites in different local time zones. [ABSTRACT FROM AUTHOR]

Published

2024

11. Advancing Crop Yield Predictions: AQUACROP Model Application in Poland's JECAM Fields.

Author

Panek-Chwastyk, Ewa, Ozbilge, Ceren Nisanur, Dąbrowska-Zielińska, Katarzyna, and Gurdak, Radosław

Subjects

*PHOTOSYNTHETICALLY active radiation (PAR), *CROP yields, *NORMALIZED difference vegetation index, *WINTER wheat, *LEAF area index, *STANDARD deviations

Abstract

This study, employing the AquaCrop model, demonstrated notable efficacy in assessing and predicting crop yields for winter wheat, maize, winter rapeseed, and sugar beets in the Joint Experiment for Crop Assessment and Monitoring (JECAM) test area of Poland from 2018 to 2023. In-situ measurements, conducted through field campaigns, included parameters such as electromagnetic radiation reflectance, Leaf Area Index (LAI), soil moisture, accumulated photosynthetically active radiation, chlorophyll content, and plant development phase. The model was calibrated with input data covering daily climatic parameters from the ERA5-land Daily Aggregated repository, crop details, and soil characteristics. Specifically, for winter wheat, the Root Mean Square Error (RMSE) values ranged from 1.92% to 14.26% of the mean yield per hectare. Maize cultivation showed RMSE values ranging from 0.21% to 1.41% of the mean yield per hectare. Winter rapeseed exhibited RMSE values ranging from 0.58% to 17.15% of the mean yield per hectare. In the case of sugar beets, the RMSE values ranged from 0.40% to 1.65% of the mean yield per hectare. Normalized Difference Vegetation Index (NDVI)-based predictions showed higher accuracy for winter wheat, similar accuracy for maize and sugar beets, but lower accuracy for winter rapeseed compared to Leaf Area Index (LAI). The study contributes valuable insights into agricultural management practices and facilitates decision-making processes for farmers in the region. [ABSTRACT FROM AUTHOR]

Published

2024

12. Tackling Difficulties When in Situ Measuring Façades U-value in Operational Stage

Author

Gaspar, Katia, Casals, Miquel, Gangolells, Marta, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Bienvenido-Huertas, David, editor, and Durán-Álvarez, Joaquín, editor

Published

2023

13. Inorganic Aerosol Precursors in the Mediterranean Atmosphere

Author

Liakakou, Eleni, Mihalopoulos, Nikolaos, Theodosi, Christina, Tsiodra, Eirini, Kaskaoutis, Dimitris G., Koukouli, Maria-Elissavet, Balis, Dimitris, Kharol, Shailesh K., Shephard, Mark W., Dammers, Enrico, Cady-Pereira, Karen E., Dulac, François, editor, Sauvage, Stéphane, editor, and Hamonou, Eric, editor

Published

2023

14. Theorical Modelling of Longitudinal Wave Propagation Emitted by a Tunnel Boring Machine in a Finite Domain

Author

Rallu, Antoine, Branque, Denis, Ceccarelli, Marco, Series Editor, Agrawal, Sunil K., Advisory Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Dimitrovová, Zuzana, editor, Biswas, Paritosh, editor, Gonçalves, Rodrigo, editor, and Silva, Tiago, editor

Published

2023

15. In-situ Measurements Frequency Analysis at a Site Scale. Application to Vibrations Induced by Tunnel Boring Machines

Author

Rallu, Antoine, Berthoz, Nicolas, Ceccarelli, Marco, Series Editor, Agrawal, Sunil K., Advisory Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Dimitrovová, Zuzana, editor, Biswas, Paritosh, editor, Gonçalves, Rodrigo, editor, and Silva, Tiago, editor

Published

2023

16. In-Situ Measurements for the Structural Monitoring of Galleria dell’Accademia di Firenze (Italy): Preliminary Results of the Tribuna

Author

Monchetti, Silvia, Bartoli, Gianni, Betti, Michele, Borri, Claudio, Gerola, Claudia, Giachetti, Andrea, Hollberg, Cecilie, Kovacevic, Vladimir C., Matta, Carlotta, Zini, Giacomo, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Wu, Zhishen, editor, Nagayama, Tomonori, editor, Dang, Ji, editor, and Astroza, Rodrigo, editor

Published

2023

17. Vehicle-Based Indirect SHM of an Austrian Railway Bridge: Simulation and In-Situ Test

Author

Reiterer, Michael, Betinelli, Lara, Stollwitzer, Andreas, Schellander, Janez, Fink, Josef, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Rizzo, Piervincenzo, editor, and Milazzo, Alberto, editor

Published

2023

18. Two-Step Correction Based on In-Situ Sound Speed Measurements for USBL Precise Real-Time Positioning.

Author

Zhao, Shuang, Liu, Huimin, Xue, Shuqiang, Wang, Zhenjie, and Xiao, Zhen

Subjects

*SOUND measurement, *SPEED measurements, *OCEAN engineering, *MARINE resources, *SPEED of sound, *HYDROGRAPHIC surveying

Abstract

The ultra-short baseline (USBL) positioning system has been widely used for autonomous and remotely operated vehicle (ARV) positioning in marine resource surveying and ocean engineering fields due to its flexible installation and portable operation. Errors related to the sound speed are a critical factor limiting the positioning performance. The conventional strategy adopts a fixed sound velocity profile (SVP) to correct the spatial variation, especially in the vertical direction. However, SVP is actually time-varying, and ignoring this kind of variation will lead to a worse estimation of ARVs'coordinates. In this contribution, we propose a two-step sound speed correction method, where, firstly, the deviation due to the acoustic ray bending effect is corrected by the depth-based ray-tracing policy with the fixed SVP. Then, the temporal variation of SVP is considered, and the fixed SVP is adaptively adjusted according to the in situ sound velocity (SV) measurements provided by the conductivity–temperature–depth (CTD) sensor equipped at the ARV. The proposed method is verified by semi-physical simulation and sea-trail dataset in the South China Sea. When compared to the fixed-SVP method, average positioning accuracy with the resilient SVP be improved by 8%, 21%, and 26% in the east, north, and up directions, respectively. The results demonstrate that the proposed method can efficiently improve the adaptability of sound speed observations and deliver better performance in USBL real-time positioning. [ABSTRACT FROM AUTHOR]

Published

2023

19. Measurement of corrosion rates on reinforcement using the field test.

Author

Koteš, Peter, Zahuranec, Michal, Prokop, Jozef, Strauss, Alfred, and Matos, Jose

Subjects

REINFORCING bars, MAINTAINABILITY (Engineering), STEEL corrosion

Abstract

Reinforcement corrosion is a phenomenon that affects not only the durability and serviceability of the structure itself but the economy of the countries, as well. In many cases, structures and bridges must be repaired or reconstructed as a result of corrosion of the reinforcement. In extreme cases, when maintenance is neglected, it is necessary to completely replace the structures with new ones, even if their planned service lifetime has not been reached ‐ it is not enough to strengthen them or it is economically inefficient. Corrosion of the reinforcement primarily causes a reduction in the cross‐sectional resistance of the load‐bearing elements by reducing the cross‐sectional area of the reinforcement, which means a reduction in the force in the reinforcement that it transmits. For this reason, it is necessary to know the rate of corrosion over time depending on the environment in which the element is located. The paper is focused on the experimental measurements of corrosion losses due to atmospheric corrosion on reinforcement samples using the field test. As a part of experimental measurements, corrosion rates on reinforcements of four diameters (diameters 6, 10, 14, and 25 mm) of steel for reinforcement, grade B 500B, are monitored at measuring stations and bridges in various aggressive environments. [ABSTRACT FROM AUTHOR]

Published

2023

20. Residual stresses and distortions in additive manufactured Inconel 718.

Author

Gullipalli, Chaitanya, Thawari, Nikhil, Burad, Prayag, and Gupta, T V K

Subjects

RESIDUAL stresses, ULTIMATE strength, THERMAL strain, TEMPERATURE measurements, HARDNESS

Abstract

Direct energy deposition is an additive manufacturing technique, follows layer-wise deposition to avail design freedom and minimizes material wastage. Despite the unique advantages, repeated heating and cooling induces thermal strains in the components. The present investigation is to understand the thermal-induced distortions and residual stresses in Inconel 718 components fabricated through direct energy deposition. The distortions and temperature measurements are carried out in situ and residual stresses are measured using micro-indentation technique. The distortions are increasing with number of layers, and the distortion rate is varying along the height of deposition. The temperature data indicated rapid heating and cooling. The residual stresses measured are compressive in nature, and are approximately 40% of yield strength in magnitude. The ultimate strength, yield strengths are 800 ± 30 MPa, 580 ± 50 MPa respectively, and maximum hardness obtained is 349 HV. Microstructure Characterizations showed continuous growth of columnar dendrites through multiple layers, and Nb segregation at interdendrites. [ABSTRACT FROM AUTHOR]

Published

2023

21. Simulation-based comparative analysis of U-value of field measurement methods

Author

Seon-In Kim, Jae-Sol Choi, Jae-Hun Jo, Jaewan Joe, Young-Hum Cho, and Eui-Jong Kim

Subjects

Thermal transmittance (U-value), Building envelope, In-situ measurements, Heat flux meter (HFM), Infrared thermography (IRT), Engineering (General). Civil engineering (General), TA1-2040

Abstract

Accurate analysis of building energy performance necessitates methodologies that can diagnose the thermal performance of a building's envelope. The building envelope contains various uncertainties and poses difficulties in verifying the measurement results, making it crucial to ensure the reliability of the measurement method. This study used dynamic simulations to verify the accuracy and reproducibility of commonly used field measurement methods. The simulation data were applied to the heat flux meter (HFM) and infrared thermography (IRT) methods to calculate the thermal transmittance of the building envelope and confirm their suitability as a field measurement method. According to the accuracy verification results, the HFM and indoor IRT (IRTi) methods, which are less affected by the external environment, evaluated the actual thermal performance of the wall close to the theoretical value with average relative errors of 3.3% and 4.2%, respectively. In the reproducibility evaluation, the HFM method exhibited similar levels of deviation over time. Additionally, to reduce the deviation in the reproducibility of the thermal transmittance derived from the IRT method, the average method was applied for data analysis, leading to a decrease in the reproducibility deviation from 36.5% to 13.3% for IRTi and from 107.3% to 71.8% for IRT outdoors (IRTo).

Published

2023

22. Geotechnical assessment of terrain strength properties on Mars using the Perseverance rover's abrading bit.

Author

Marteau, Eloïse, Wehage, Kristopher, Higa, Shoya, Moreland, Scott, and Meirion-Griffith, Gareth

Subjects

*MEASUREMENT of shear strength, *REGOLITH, *SCIENTIFIC apparatus & instruments, *MARS (Planet), *MARTIAN exploration, *GEOTECHNICAL engineering

Abstract

• To date, geotechnical instrumentation has been absent from Mars missions. • The Perseverance rover's abrading bit has a similar form factor to a Bevameter. • We study the use of the abrading bit tool to perform soil strength measurements. An instrument for measuring the geotechnical properties of the Martian soil provides high-value science opportunities and high-priority mission-support capabilities that serve reconnaissance, science, and engineering. Such instrument can be used to characterize the terrain for drilling, landing, trafficability, and other surface operations. However, to date, instruments for measuring geotechnical properties have been absent from Mars exploration missions. This paper examines the use of the Mars 2020 Perseverance rover's abrading bit tool to perform regolith strength measurements. The Perseverance rover's abrading bit has a similar form factor to a Bevameter, a tool commonly used to collect engineering geotechnical data to assess terrain traversability. To demonstrate a methodology by which the abrading bit can be employed to characterize soil strength, a portable testbed that mimics the flight system is designed and built using commercial off-the-shelf components. A data-processing pipeline is developed to convert raw measurements to soil strength. Tests were performed on three characterized simulants with different mechanical properties. The results show that the abrading bit is capable of making shear and bearing strength measurements with quantified uncertainties and demonstrate, for the first time, the ability to perform controlled geotechnical analysis using a standard science instrument. [ABSTRACT FROM AUTHOR]

Published

2023

23. A Novel Near-Surface Wave-Coherent Instantaneous Profiling System for Atmospheric Measurements.

Author

Stanek, Mathew J., Pastore, Douglas M., and Hackett, Erin E.

Subjects

*ATMOSPHERIC boundary layer, *OCEAN waves, *ATMOSPHERIC water vapor measurement, *HUMIDITY, *BOUNDARY layer (Aerodynamics), *METEOROLOGICAL stations

Abstract

Large knowledge gaps concerning the effect of ocean surface waves on near-surface vertical distributions of temperature and humidity exist due to practical limitations and sensor fidelity challenges of direct measurements. Measurements of temperature and humidity are classically made using rocket- or radiosondes and fixed weather stations and can utilize a tethered profiling system. However, these measurement systems have limitations when obtaining wave-coherent measurements near the sea surface. Consequently, boundary layer similarity models are commonly employed to fill in near-surface measurement gaps despite the documented shortcomings of the models in this region. Thus, this manuscript presents a near-surface wave-coherent measurement platform that measures high-temporal-resolution vertical distributions of temperature and humidity down to ~0.3 m above the instantaneous sea surface. The design of the platform is described along with preliminary observations obtained during a pilot experiment. Ocean surface-wave phase-resolved vertical profiles are also demonstrated from the observations. [ABSTRACT FROM AUTHOR]

Published

2023

24. Coherent Gradient Sensing Spatial Carrier Method and its Application for In-Situ Dynamic Deformation Monitoring in Laser Repair Process.

Author

Li, J., Zhong, Q., Xie, H., and He, W.

Subjects

*DEFORMATIONS (Mechanics), *DIFFRACTION patterns, *STRAIN gages, *CURVATURE measurements, *MEASUREMENT errors, *MICROPLATES

Abstract

Background: As a 3D printing technology, directed energy deposition (DED) has been offering key advantages in additive manufacturing and repair sectors. However, extreme manufacturing processes, such as complex multi-physics coupling process, have brought issues and challenges to the quality and repeatability of DED products. In-situ monitoring in DED process could provide a powerful tool to meet this challenge, and has attracted extensive attention from academic and engineering fields. Objective: In this study, a novel coherent gradient sensing spatial carrier method (CGS-SCM) based on designed prism is proposed for the in-situ monitoring of deformation evolution of DED repaired components. Methods: The measurement principle of the CGS-SCM is analyzed, the governing equations are deduced, and the phase of CGS fringe patterns with carriers are calculated using the sample moiré technique. Moreover, two groups of prisms for carrier generation are designed and integrated into the CGS system, and the new system is verified through the curvature measurement of spherical mirror and the standard four-point beam bending test. Results: Results show that the spatial carrier method could improve both the efficiency and accuracy of data analysis, and the relative error for curvature measurement is less than 2% compared with the strain gauge method. As an application, the evolution rules of the full-field residual deformation of DED repaired components are monitored in situ using the improved CGS system. With the increase of cooling time, the residual deformation shows significant anisotropy and changes in value. In deposition direction, the deformation value gradually increases and the distribution characteristic varies significantly; however, in scanning direction, only the deformation value changes, while the distribution characteristic remains unchanged. Moreover, the deformation in deposition direction is always smaller than that in scanning direction throughout the cooling process. Conclusions: This study indicates that the CGS-SCM based on prisms solves the problem of introducing spatial carriers into CGS optical path, which provides a new way to in-situ analyze the dynamic deformation more efficiently and accurately in DED repair process. [ABSTRACT FROM AUTHOR]

Published

2023

25. Microstructure Evolution in Mg98.6Y1Zn0.4 Alloys and the Development by Hot Deformation Examined by Synchrotron Radiation Small- and Wide-Angle Scattering.

Author

Hiroshi Okuda, Yoshiaki Maegawa, Kento Shimotsuji, Shin-ichi Inoue, Yoshihito Kawamura, and Shigeru Kimura

Subjects

SYNCHROTRON radiation, HOT rolling, MICROSTRUCTURE, SUPERSATURATED solutions, CRYSTAL grain boundaries

Abstract

Synchrotron radiation small- and wide-angle scattering measurements have been performed for Mg98.6-Y1-Zn0.4 alloys. In the early stage of phase transformation from supersaturated solid solutions, isotropic scattering suggesting segregation at grain boundaries was observed. It grew with temperature during heating the sample at a constant rate of 0.133K/s. Above 600K where introduction of stacking faults is expected, needle-like scattering became visible, which represents platelet shape segregation of cluster layers called cluster arranged layer (CAL). The layer eventually developed to form multiple layers, cluster arranged nano plates (CANaP) at higher temperatures. Microstructure change by hot rolling after the heat treatments has been examined from a viewpoint of kink-deformed microstructures. [ABSTRACT FROM AUTHOR]

Published

2023

26. Estimating the Role of Bank Flow to Stream Discharge Using a Combination of Baseflow Separation and Geochemistry.

Author

Hofmann, Harald

Subjects

STREAMFLOW, BASE flow (Hydrology), GEOCHEMISTRY, RIPARIAN areas, WATERSHEDS, HYDROGEOLOGY

Abstract

This study investigated the role of bank return flow to two medium size rivers in southeast Queensland using a combination of hydrograph separation techniques and geochemical baseflow separations. The main aims were to provide a case study to demonstrate spatial and temporal variability in groundwater contributions to two river systems in Southeast Victoria; the Avon River and the Mitchell River. The two rivers show large spatial and temporal variations in groundwater contributions with higher percentages during low flow periods and more surface runoff during wet years. At the end of the Australian millennium drought, groundwater discharge accounted for 60% of the total flow for the Avon River and 42% for the Michell River, whereas groundwater discharge only had a minor component to the total discharge in wetter years, ∼15% for the Avon River and only 3% for the Mitchell River. Radon and chloride were used for the geochemical baseflow separation and provide a means to separate regional groundwater discharge to the rivers from bank return flow. Bank return flow accounts for 2 to 5 times higher fluxes in certain areas. Geochemistry in combination with physical hydrogeology enhances the overall understanding of groundwater connected river systems over the river length. [ABSTRACT FROM AUTHOR]

Published

2023

27. THM-coupled numerical analysis of temperature and groundwater level in-situ measurements in artificial ground freezing

Author

A. Kostina, M. Zhelnin, O. Plekhov, and K.A. Agutin

Subjects

saturated freezing soil, artificial ground freezing, thermo-hydro-mechanical model, in-situ measurements, ice wall integrity, Mechanical engineering and machinery, TJ1-1570, Structural engineering (General), TA630-695

Abstract

Belarusian Potash salt deposits are bedded under aquifers and unstable soil layers. Therefore, to develop the deposits a vertical mine shaft sinking is performed using the artificial ground freezing technology. Nowadays, real-time observations of ground temperature and groundwater level is applied to control the ground freezing process. Numerical simulation can be used for a comprehensive analysis of measurements results. In this paper, a thermo-hydro-mechanical model of freezing for water-saturated soil is proposed. The governing equations of the model are based on balance laws for mass, energy and momentum for a fully saturated porous media. Clausius-Clayperon equation and poroelastic constitutive relations are adopted to describe coupled processes in water and ice pore pressure, porosity and a stress-strain state of freezing soil. The proposed model was used to predict equivalent water content measured in Mizoguchi�s test and frost heave in a one-sided freezing test. Numerical simulation of ground freezing in the Petrikov mining complex located in Belarus has shown that the model is able to describe field measurements of pore pressure inside a forming frozen wall. Furthermore, the mismatch between hydro- and thermo-monitoring data obtained during the artificial freezing is analyzed.

Published

2022

28. Internal forces measured in segmental tunnel linings compared with numerical predictions obtained from state-of-the-art calculation methods used in engineering practice.

Author

Rauch, Fabian, Oreste, Pierpaolo, and Fischer, Oliver

Subjects

*STRUCTURAL design, *TUNNEL lining, *STRUCTURAL models, *BENDING moment, *STRUCTURAL health monitoring, *TUNNELS

Abstract

• Analytical methods and numerical models can determine accurately inner forces in segmental lining. • A comparison is useful between calculation results and in situ monitoring. • Assembly imperfections influence the development of bending moments in segmental linings. • Some common modeling approaches might underestimate the stresses in tunnel linings. • The whole possible parameter bandwidth should be investigated in structural design. Different calculation methods and modeling strategies are commonly used in engineering practice to predict the internal forces in segmental tunnel linings. Accordingly, the calculation results can differ. The present paper compares internal forces resulting from five state-of-the-art calculation models, of which three continuum models and two bedded beam models, to new in-situ measurements of internal forces at the recently built TBM tunnel for the U5 metro line in Frankfurt, Germany, and discusses agreements and differences. Hereby, a generally good agreement is found for the normal forces. The predictions of the bending moments are satisfying, but there are some discrepancies. It is shown that it might be necessary to consider assembly imperfections in the calculation models to improve the agreement between the calculation results and the measurements. Also, the differences between the calculation methods themselves are addressed. It is analyzed that generally continuum models give more realistic internal forces, but that also bedded beam models can have advantages, e.g. when large parametric studies are required. Finally, recommendations are given regarding the application of calculation models for structural design. [ABSTRACT FROM AUTHOR]

Published

2024

29. Landsat/MODIS Fusion for Soil Moisture Estimation Over a Heterogeneous Area in Northern Jordan.

Author

Almagbile, Ali, Hazeymeh, Khaled, Mosleh, Mostafa, Al-Rawabdeh, Abdulla, Aldayafleh, Omar, Zeitoun, Mohammad, and Maslamani, Amer

Subjects

SOIL moisture, REMOTE sensing, SPECTRORADIOMETER, GEOLOGICAL statistics, LAND surface temperature

Abstract

Fusion models have been developed to improve the spatial and temporal resolution simultaneously because remote sensing data cannot guarantee the high resolution of vegetation and temperature products. In this study, Moderate Resolution Imaging Spectroradiometer (MODIS) and Land Remote Sensing Satellite (Landsat) data were fused using the STI-FM fusion model for retrieving soil moisture index (SMI) based on the NDVI-LST triangulation/trapezoidal shape. The study was conducted from November 2019 to May 2020 and covered a heterogeneous area in Northern Jordan. For validation, the soil moisture index results were then compared with the observed in-situ soil moisture measurements at 16 sites distributed throughout the study area. To determine the spatial and temporal variability/stability of SMI and observed soil moisture, statistical and geostatistical approaches were employed. The results revealed that the relationship between SMI and in-situ measurements was high in the wet winter months and low during the warm summer months. The determination coefficient r2 of 0.66 and RMSE of 0.10 were found in January while in May, the r2 and RMSE were 0.35 and 0.32, respectively. The results of the semivariogram analysis showed that the observed soil moisture was more varied during the wet periods when compared with the drier period, whereas the SMI was not influenced by seasonal variations. The results indicated that high values of SMI can be obtained with low temperature and rich vegetation, while the higher temperature and water-stressed vegetation revealed low SMI values. [ABSTRACT FROM AUTHOR]

Published

2022

30. Evaluation of Aerosol Typing with Combination of Remote Sensing Techniques with In Situ Data during the PANACEA Campaigns in Thessaloniki Station, Greece.

Author

Voudouri, Kalliopi Artemis, Michailidis, Konstantinos, Siomos, Nikolaos, Chatzopoulou, Anthi, Kouvarakis, Georgios, Mihalopoulos, Nikolaos, Tzoumaka, Paraskevi, Kelessis, Apostolos, and Balis, Dimitrios

Subjects

*SOOT, *REMOTE sensing, *AEROSOLS, *PARTICULATE matter, *BIOMASS burning, *ATMOSPHERIC physics

Abstract

Two measurement campaigns were conducted at Thessaloniki, an urban station, (40.5°N, 22.9°E; 60 m) in the frame of the PANhellenic infrastructure for Atmospheric Composition and climatEchAnge (PANACEA) project. The first one covers the period from July to August 2019 and the second one from January to February An overview of the aerosol optical properties (columnar and height resolved), acquired with the remote sensing infrastructure of the Laboratory of Atmospheric Physics (LAP) of the Aristotle University of Thessaloniki (AUTH), as well as the additional instrumentation that participated during the PANACEA campaigns is presented. The majority of the detected layers (16 out of 40, ranged between 0.8 and 4.5 km) are classified as biomass burning aerosols, attributed to either city sources or long range transport. Concerning the other aerosol types, the Clean Continental cluster has an occurrence ratio of 23%, while dust layers and mixtures with urban particles transported to Thessaloniki are also identified. Our findings are discussed along with the surface information, i.e., the particulate matter (PM2.5 and PM10) concentrations and the black carbon (BC) concentration, separated into fossil fuel (BCff) and biomass/wood burning (BCwb) fractions. This is the first time that collocated in situ and remote sensing instruments are deployed in Thessaloniki in order to assess the presence of aerosols and the predominant aerosol type both in situ and at elevated heights. Overall, our study showed that the BCwb contribution to the BC values in Thessaloniki is quite low (11%), whilst the majority of the biomass burning layers identified with the lidar system, are also linked with enhanced BC contribution and high Fine Mode Fraction values. [ABSTRACT FROM AUTHOR]

Published

2022

31. Insights on gas hydrate formation and growth within an interbedded sand reservoir from well logging at the Qiongdongnan basin, South China Sea.

Author

Kang, Dongju, Zhang, Zijian, Lu, Jing'an, Phillips, Stephen C., Liang, Jinqiang, Deng, Wei, Zhong, Chao, and Meng, Dajiang

Subjects

*GAS hydrates, *GAS reservoirs, *GAMMA rays, *SAND, *ANISOTROPY

Abstract

Although variable well log resolution and its control on saturation estimation has been studied, it has not been directly applied to a specific location to explore the nature of gas hydrate within a sand reservoir. We applied in-situ measurements of resistivities, neutron porosity, and gamma ray at two sites in the Qiongdongnan Basin, South China Sea (QDN-W05–2021 and QDN-W08–2021) to investigate the reservoir parameters of a hydrate-bearing sand reservoir. Our results show that gas hydrate is distributed in 5 zones with a total thickness of 10.7 m and an average saturation of 69% at the QDN-W05–2021 site, while they are distributed in 2 zones with a total thickness of 4.3 m and an average saturation of 49% at the QDN-W08–2021 site. We found that variances in saturations estimated from lateral-extra deep button (RX), phase shift (P40H-P40L), and attenuation (A40H-A40L) resistivities within the laterally mapped continuous sand body were affected by the nature of gas hydrate occurrences. Results indicate gas hydrate forms and accumulates at the center of the sand layer and tends to be less or not present toward the top and base. Integrated with seismic data, the in-situ measurements provide insights in the evolution of a mushroom-shaped, hydrate-gas reservoir system. In the system, free gas is likely horizontally transported from the top-center of the gas chimney to the surrounding areas in the early stage dominated by a warm-gas environment, whereas hydrate forms in the opposite pathway starting from the surrounding areas in the following stage with temperature reducing. Our study suggests that high-resolution in-situ measurements not only are a tool to identify the physical properties, but also can be used to help explain the physical process of hydrate growth and accumulation. • We identify a hydrate-bearing sand reservoir with multiple thin, horizontal beds. • Mushroom-shape hydrate-gas system via lateral fluid movement from a gas chimney. • Thin, lateral-bedding hydrate layers results in electrical anisotropy. • Thin gas hydrate reservoir shows more pronounced saturation scale effects. • Vertical resolution of resistivity tools influences hydrate saturation estimates. [ABSTRACT FROM AUTHOR]

Published

2024

32. Measuring lubricant viscosity at a surface and in a bearing film using shear-horizontal surface acoustic waves.

Author

Tyreas, G., Dwyer-Joyce, R.S., Notay, R.S., and Durham, D.J.

Abstract

The lubricating effectiveness of an oil film in a journal bearing depends on the dynamic viscosity of the oil. The viscosity in turn depends on the local operating temperature, pressure, and shear rate. Reproducing these conditions in a laboratory viscometer to investigate the lubricant behaviour is a challenging task. As a result, methods that allow oil viscosity measurement in-situ in a film, would be preferred. Ultrasound technology utilising shear bulk acoustic waves (BAW) has been used to measure liquid viscosity in the bulk, as well as in-situ in a film; the reflection of a shear BAW from a solid-liquid interface depends on the liquid viscosity. Surface acoustic waves (SAW) have been also used for measuring bulk liquid viscosity. In this paper, shear-horizontal surface acoustic waves (SH-SAWs) were explored for measuring oil film viscosity, as they present good coupling with liquids and sensitivity to surface changes. The main objectives of this work were to generate SH-SAWs on metallic media, investigate the wave response at the metal-oil interface, relate the wave response to viscosity with the aim to apply this knowledge to a journal bearing application for measuring viscosity in-situ the lubricant film. Initially, the SH-SAW response was investigated at a solid-liquid interface. SH-SAWs attenuate at the solid-liquid interface, due to the liquid viscosity. This was modelled as a function of the liquid properties, material and geometry of the medium, and wave frequency. The SH-SAW attenuation-viscosity model was used to calculate the viscosity (in the range of ∼3 to 4600 cP) of different oils at a free surface, which agreed with the viscosity values from datasheets and bench-top viscosity measurements. This approach was then implemented in-situ in a journal bearing application. A bearing sleeve was instrumented with a pair of SH-SAW transducers and a shear BAW transducer installed inside the rotating journal. These two approaches were used to measure the film viscosity of 4 lubricants blended with different additives in two ways; the former by the leakage of the surface wave, and the latter by the reflection of the bulk wave. Both approaches were found to be in good agreement. They successfully distinguished the chemistry of the oil test samples according to their viscosities under various loading conditions and constant speed, and were able to monitor changes in the oil film viscosity in the loaded region. The SH-SAW sensors used were low cost and small sized and so can be fitted relatively conveniently into a bearing sleeve, requiring nothing but a function generator and digitiser to operate. This approach could then be used to evaluate lubricant formulations for their performance actually inside a bearing, rather than through the extrapolation of data from a conventional bench top viscometer. [ABSTRACT FROM AUTHOR]

Published

2022

33. THM-coupled numerical analysis of temperature and groundwater level in-situ measurements in artificial ground freezing.

Author

Kostina, A., Zhelnin, M., Plekhov, O., and Agutin, K. A.

Subjects

GROUNDWATER temperature, WATER table, GROUNDWATER analysis, NUMERICAL analysis, PORE water pressure, POROELASTICITY

Abstract

Belarusian Potash salt deposits are bedded under aquifers and unstable soil layers. Therefore, to develop the deposits a vertical mine shaft sinking is performed using the artificial ground freezing technology. Nowadays, real-time observations of ground temperature and groundwater level is applied to control the ground freezing process. Numerical simulation can be used for a comprehensive analysis of measurements results. In this paper, a thermo-hydro-mechanical model of freezing for water-saturated soil is proposed. The governing equations of the model are based on balance laws for mass, energy and momentum for a fully saturated porous media. Clausius-Clayperon equation and poroelastic constitutive relations are adopted to describe coupled processes in water and ice pore pressure, porosity and a stress-strain state of freezing soil. The proposed model was used to predict equivalent water content measured in Mizoguchi's test and frost heave in a one-sided freezing test. Numerical simulation of ground freezing in the Petrikov mining complex located in Belarus has shown that the model is able to describe field measurements of pore pressure inside a forming frozen wall. Furthermore, the mismatch between hydro- and thermo-monitoring data obtained during the artificial freezing is analyzed. [ABSTRACT FROM AUTHOR]

Published

2022

34. Physical and Chemical Properties of Cloud Droplet Residuals and Aerosol Particles During the Arctic Ocean 2018 Expedition.

Author

Karlsson, Linn, Baccarini, Andrea, Duplessis, Patrick, Baumgardner, Darrel, Brooks, Ian M., Chang, Rachel Y.‐W., Dada, Lubna, Dällenbach, Kaspar R., Heikkinen, Liine, Krejci, Radovan, Leaitch, W. Richard, Leck, Caroline, Partridge, Daniel G., Salter, Matthew E., Wernli, Heini, Wheeler, Michael J., Schmale, Julia, and Zieger, Paul

Subjects

CLOUD droplets, CHEMICAL properties, CLOUD condensation nuclei, AEROSOLS, PARTICLE size distribution, SOLVENT extraction, CARBONACEOUS aerosols, SEA ice

Abstract

Detailed knowledge of the physical and chemical properties and sources of particles that form clouds is especially important in pristine areas like the Arctic, where particle concentrations are often low and observations are sparse. Here, we present in situ cloud and aerosol measurements from the central Arctic Ocean in August–September 2018 combined with air parcel source analysis. We provide direct experimental evidence that Aitken mode particles (particles with diameters ≲70 nm) significantly contribute to cloud condensation nuclei (CCN) or cloud droplet residuals, especially after the freeze‐up of the sea ice in the transition toward fall. These Aitken mode particles were associated with air that spent more time over the pack ice, while size distributions dominated by accumulation mode particles (particles with diameters ≳70 nm) showed a stronger contribution of oceanic air and slightly different source regions. This was accompanied by changes in the average chemical composition of the accumulation mode aerosol with an increased relative contribution of organic material toward fall. Addition of aerosol mass due to aqueous‐phase chemistry during in‐cloud processing was probably small over the pack ice given the fact that we observed very similar particle size distributions in both the whole‐air and cloud droplet residual data. These aerosol–cloud interaction observations provide valuable insight into the origin and physical and chemical properties of CCN over the pristine central Arctic Ocean. Key Points: Aitken‐mode particles contributed significantly to cloud droplet formation in the high Arctic, especially after the transition to fallResidence time over the pack ice and the relative contribution of organics both increased when average particle size decreasedAddition of aerosol mass due to aqueous‐phase chemistry was probably small over the pack ice [ABSTRACT FROM AUTHOR]

Published

2022

35. Hydrological monitoring of a slope covered by stratified pyroclastic deposits and analysis of infiltration processes.

Author

Capparelli, Giovanna and Spolverino, Gennaro

Subjects

SOIL infiltration, VOLCANIC soils, SOIL profiles, RAIN gauges, VOLCANIC ash, tuff, etc., PUMICE, SOIL moisture

Abstract

In addition to the duration and intensity of rainfall, infiltration processes are strongly affected by the hydraulic properties of the soil. In the case of heterogeneous and stratified soil profiles, the analysis of the infiltration process becomes more complex, since conflicting hydraulic properties of adjacent layers can induce locally diverted flow. Soils of volcanic origin present these characteristics, because during the various eruptive phases, layers with very different textures are deposited. In this article, data are analysed which have been recorded by a monitoring station installed on a slope made up of volcanic deposits. The station consists of a rain gauge to measure rainfall and seven tensiometers and eight TDR probes installed at different depths to measure suction and volumetric water content, respectively. The slope is made up of alternating volcanic ash (silt‐sandy‐clay paleosoils) interspersed with pumice (sandy‐gravel), due to the different eruptive phases of the volcanic complexes in the area. The analysis of the data established that the layers of coarser material (pumices), depending on the initial moisture conditions, may hinder or even favour the infiltration of water into the deeper layers. In particular, when water content is low, the pumices presented a low unsaturated conductivity which hindered infiltration. By contrast, in wetter conditions, they favoured the flow of water. Therefore, the initial moisture conditions of the soil layers must be taken into account for a correct prediction of the infiltration phenomena. Dry conditions of the pumice layers can hinder drainage into the lower layers, thus favouring the rapid accumulation of soil water during rainfall events, which could eventually lead to slope failure. [ABSTRACT FROM AUTHOR]

Published

2022

36. Full-scale long-term monitoring of mine-induced vibrations for soil-structure interaction research using dimensionless response spectra

Author

Krystyna Kuzniar and Tadeusz Tatara

Subjects

Mine-induced vibrations, Long-term monitoring, In-situ measurements, Soil-structure interaction, Dimensionless response spectra, Empirical models, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

This article presents the application of data from the real-time full-scale long-term monitoring of mine-induced vibrations in one of the mining districts in Poland in the study of the soil-structure interaction (SSI) effect. Mining-related surface vibrations constitute a burdensome and essential problem in mining areas all over the world because underground exploitation results in so-called induced seismicity with a negative vibration impact on the environment and may damage structures. Mining tremors are similar to natural earthquakes due to, for example, their randomness, lack of human control, time and place of their occurrence and energy magnitude. As a consequence of the SSI phenomenon, mine-induced vibrations concurrently measured on the free-field near to the building and at the building foundation level may differ significantly. Long-term measurements using dynamic tensometers permit the establishment of strength states in structural elements and the evaluation of the health of materials and structures. Long-term observations also indicate the development of damage over time and its propagation in the structure. Dimensionless response spectra (β) were applied for describing the seismic-type loads from mine-induced tremors – such spectra are found in many design codes. An evaluation of the influence of mining parameters (epicentral distance, energy magnitude, peak ground acceleration) on the process of the transition of ground accelerations to the structure foundations was performed using curves of ratios of β from vibrations recorded concurrently on the free-field and in the building foundation. The strong influence of the rockburst parameters on β curves achieved with the application of free-field and foundation mining-related records is observed. A similar conclusion applies to the ratios of β concerning low-, medium-, and high-rise buildings with different load-bearing systems. Furthermore, based on the results obtained from measurement data, empirical models for the simple estimation of the SSI effect were proposed.

Published

2022

37. Comparison of temperature and displacement measurements with load simulations for the determination of Process Signatures.

Author

Frerichs, F., Tausendfreund, A., and Lübben, Th.

Abstract

Heat exchange between environment and workpiece during a manufacturing process can lead to temperature gradients and strains within the workpiece and can result in residual stresses. The correlations between the generated thermal loads and the resulting modifications are called Process Signature. The presented investigations were performed to validate residual stress calculations for laser hardening. Furthermore, the potential of speckle photography for in-situ measurement of displacements as an additional result for simulation validation were evaluated. [ABSTRACT FROM AUTHOR]

Published

2022

38. A Portable Battery-Operated Sensor System for Simple and Rapid Assessment of Virgin Olive Oil Quality Grade †.

Author

Grossi, Marco, Valli, Enrico, Bendini, Alessandra, Gallina Toschi, Tullia, and Riccò, Bruno

Subjects

OLIVE oil, K-nearest neighbor classification, CHEMICAL reagents, DISTILLED water, LABORATORY personnel

Abstract

Virgin olive oil quality is assessed by chemical as well as sensory analysis. Two of the most important parameters that define the quality of virgin olive oils are the free acidity and the peroxide index. These chemical parameters are usually determined by manual titration procedures that must be carried out in a laboratory by trained personnel. In this paper, a portable sensor system to support the quality grade assessment of virgin olive oil is presented. The system is battery operated and characterized by small dimensions, light weight and quick measurement response (about 30 s). The working principle is based on the measurement of the electrical conductance of an emulsion between a chemical reagent and the olive oil sample. Two different chemical reagents have been investigated: (1) a hydro-alcoholic solution (HAS), made of 60% ethanol and 40% distilled water; (2) 100% distilled water (DW). Tests have been carried out on a set of 40 olive oil samples. The results have shown how, for most of the fresh virgin olive oil samples (31 samples out of 40), the free acidity can be estimated with good accuracy from the electrical conductance of the emulsion using HAS as the reagent. In the case of the full set of samples, the emulsion electrical conductance, using HAS as the reagent, is a function of both the sample free acidity as well as the compounds produced by oil oxidation, and a compensation method based on the measured electrical conductance, using DW as the reagent, has been introduced to improve the accuracy in the estimated free acidity. Tests have also been carried out on the full set of samples, using a k-nearest neighbors algorithm, to demonstrate the feasibility of olive oil classification according to the quality grade. The results have shown how measurements carried out using only the HAS reagent provide better classification accuracy than measurements carried out using both the HAS and DW reagents. The proposed system can be a low-cost alternative to standard laboratory analyses to evaluate the quality grade of virgin olive oil. [ABSTRACT FROM AUTHOR]

Published

2022

39. Enhancing hygrothermal monitoring of wet construction with digital twins.

Author

Pereira, Pedro F., Vidal, João, and Ramos, Nuno M.M.

Subjects

LIGHTWEIGHT concrete, DIGITAL twins, MOISTURE in concrete, MOISTURE meters, GRAVIMETRIC analysis, STRUCTURAL health monitoring, HYGROTHERMOELASTICITY

Abstract

The development of digital building twins in the Architecture, Engineering, Construction and Operation (AECO) sector requires the adoption of adequate monitoring strategies for building components. This article presents a proposal and validation of a digital twin-enabled hygrothermal monitoring procedure applied to lightweight concrete using an IoT Arduino-based prototype. This study conducted tests to measure moisture in three types of lightweight concrete for over a year. Temperature and relative humidity sensors were embedded in the lightweight concrete samples. The recorded data were compared to four in-situ surface moisture meters and gravimetric analysis. Although surface moisture meters have different reference scales, the qualitative assessment is similar. The embedded sensors preserved their performance levels during the entire testing period, even those exposed to relative humidity levels near 100 %. The continuous monitoring of temperature and relative humidity in non-structural construction elements, using low-cost sensors embedded during construction, is proven to be viable. [Display omitted] • Assessment of the drying process of lightweight concrete with three different densities. • Moisture monitoring in digital building twins can prevent building pathologies. • Over the 425-day testing period, the low-cost sensors exhibited no degradation. • Surface moisture meters with a capacity of sensing deeper provides better accuracy. • At 20 °C/30 %, samples with 800 kg/m³ takes over 4 times longer to dry than with 525 kg/m³. [ABSTRACT FROM AUTHOR]

Published

2024

40. Life on the edge: Adaptations of Posidonia oceanica to hypersaline conditions in a Mediterranean lagoon system

Author

Università degli Studi di Palermo, Mancuso, Francesco Paolo, Bernardeau-Esteller, Jaime, Spinelli, M., Sará, G., Ruiz-Fernández, Juan Manuel, Calvo, S., Tomasello, A., Università degli Studi di Palermo, Mancuso, Francesco Paolo, Bernardeau-Esteller, Jaime, Spinelli, M., Sará, G., Ruiz-Fernández, Juan Manuel, Calvo, S., and Tomasello, A.

Abstract

Hypersaline stress is a major stressor in semi-enclosed coastal lagoons, affecting the distribution and survival of key foundation species. In this study, we investigated how Posidonia oceanica meadows responded physiologically and morphologically to different salinity concentrations both in-situ, across a natural saline gradient occurring inside the lagoon system, and in a mesocosm experiment. Leaf water relations, organic osmolytes, photosynthesis, respiration, Chlorophyll-a fluorescence, pigments content, and leaf growth were studied in P. oceanica from three different sites within the Stagnone of Marsala lagoon, as well as after exposing P. oceanica to a salinity level of 46 psu in a 30-day mesocosm experiment. Overall, we show that P. oceanica has evolved osmolar regulatory strategies and photosynthetic plasticity, allowing these meadows to cope with large salinity fluctuations (38 – 51.45 PSU). Our findings contribute to a better understanding of seagrass ecophysiological adaptation to extreme environmental conditions, as well as the importance of these populations serving as an experimental model at the Mediterranean scale for more comprehensive forecasting and management of environmental stress in these marine foundation species in an era of rapid environmental change.

Published

2023

41. Behaviour of a ducted twin vertical axis tidal turbine in a diversity of flow conditions at sea and in a flume tank

Author

Moreau, Martin and Moreau, Martin

Abstract

Limiting human-caused global warming requires, among other adaptations, a substantial reduction of fossil fuel use and a widespread electrification based on low greenhouse gas emission production systems. In this context, harnessing the tidal current energy and other marine renewable energy sources has gained interest for the last decade, which lead to the first offshore tests for several tidal energy converter concepts. Among them, the first 1 megawatt ducted twin vertical axis tidal turbine prototype, developed by HydroQuest, was tested off the northern coast of Brittany, France, from 2019 to 2021. In the prospect of the next turbine generations, the company wants to improve its experimental and numerical design tools to gain confidence in its capacity to predict the full-scale performance and loads from the experiments at reduced-scale. That can only be done by comparing the results obtained at sea to those obtained in the laboratories to assess the potential scale effects. Therefore, we first analyse the measurements at sea to characterise the behaviour of the prototype. Then, we study the response of a 1/20 scale model of that prototype tested in the Ifremer wave and current flume tank in Boulogne-sur-mer, France. We consider many flow conditions, increasing the complexity from idealised towards more realistic conditions. Beyond the comparison between reduced- and full-scale results, the analyses presented in that thesis also aim at better understanding the influence of each of the tidal current flow characteristics on the ducted turbine. In more details, from power performance, loads and wake measurements, we study the effects of the incident flow shear, of the relative flow direction, of the turbulence generated by bathymetry obstacles and of surface waves on the model response. The results show that the average power performance is rather insensitive to the incident flow conditions whereas the power and load fluctuations can be strongly affected. Finally, we, Limiter le réchauffement climatique nécessite, entre autres adaptations, une réduction substantielle de l’utilisation des énergies fossiles et une électrification généralisée basée sur des systèmes de production faiblement émetteurs de gaz à effet de serre. Dans ce contexte, l’exploitation de l’énergie des courants de marée et autres énergies marines renouvelables gagne en intérêt. Ainsi, la dernière décennie a vu les premiers essais en mer de plusieurs concepts d’hydroliennes. Parmi eux, la première hydrolienne carénée à double axe vertical de 1 mégawatt, développée par HydroQuest, a été testée au large de l’île de Bréhat, en Bretagne, de 2019 à 2021. Dans la perspective des prochaines générations de turbines, l’entreprise souhaite améliorer ses outils de conception expérimentaux et numériques afin de gagner en confiance dans sa capacité à prédire les performances et les chargements mécaniques à l’échelle réelle à partir des expériences à échelle réduite. Cela ne peut se faire qu’en comparant les résultats obtenus en mer à ceux obtenus en laboratoire afin d’évaluer les potentiels effets d’échelle. Par conséquent, nous commençons ce mémoire par l’analyse des mesures en mer pour caractériser le comportement du prototype in-situ. Ensuite, nous étudions la réponse d’une maquette à l’échelle 1/20 de ce prototype à partir d’essais réalisés dans le bassin à houle et courant de l’Ifremer à Boulogne-sur-mer. Nous considérons de nombreuses conditions d’écoulement, allant de conditions idéales vers des conditions plus complexes et réalistes. Au-delà de la comparaison des résultats entre échelle réduite et échelle réelle, les analyses présentées dans cette thèse visent également à mieux comprendre l’influence de chacune des caractéristiques de l’écoulement des courants de marée sur le comportement de l’hydrolienne carénée. À partir de mesures de puissance, d’efforts et de sillage, nous étudions les effets du cisaillement de l’écoulement incident, de sa direction relative, de l

Published

2023

42. THM-coupled numerical analysis of temperature and groundwater level in-situ measurements in artificial ground freezing

Author

Anastasiia Kostina, Maxim Zhelnin, Oleg Plekhov, and Kirill Agutin

Subjects

In-situ measurements, Mechanics of Materials, Mechanical Engineering, Artificial ground freezing, Saturated freezing soil, Analytical, computational and physical Models, Structural Integrity, Thermo-hydro-mechanical model, Ice wall integrity, Civil and Structural Engineering

Abstract

Belarusian Potash salt deposits are bedded under aquifers and unstable soil stratums. Therefore, to develop the deposits a vertical mine shaft sinking is performed using the artificial ground freezing technology. Nowadays, real time observations of ground temperature and groundwater level is applied to control the ground freezing process. Numerical simulation can be used for a comprehensive analysis of measurements results. In this paper a thermo-hydro-mechanical model of freezing of water saturated soil is proposed. The governing equations of the model are based on balance laws for mass, energy and momentum for a fully saturated porous media. Clausius-Clayperon equation and poroelastic constitutive relations are adopted for description of a coupled change in water and ice pore pressure, porosity and a stress-strain state of freezing soil. The proposed model enables us to describe evolution of equivalent water content measured in Mizoguchi’s test and predict frost heave strain in one-sided freezing test. Numerical simulation of ground freezing in the Petrikov mining complex located in Belarus has shown that the model is able to describe field measurements of pore pressure inside a forming frozen wall. Furthermore, the mismatch between hydro- and thermo-monitoring data obtained during the artificial freezing is analyzed.

Published

2022

43. Advancing efficiency and reliability in thermal analysis of laser powder-bed fusion.

Author

Scheel, Pooriya, Wrobel, Rafal, Rheingans, Bastian, Mayer, Thomas, Leinenbach, Christian, Mazza, Edoardo, and Hosseini, Ehsan

Subjects

*LASER fusion, *LASER beams, *THERMAL analysis, *THERMAL efficiency, *MULTISCALE modeling, *RESIDUAL stresses

Abstract

In laser based powder-bed fusion of metals (PBF-LB/M), parts are fabricated by melting layers of powder using a high-intensity laser beam. During this process, the material is exposed to rapid cooling rates and intense thermal gradients, which are the underlying causes of residual stress formation and development of a unique microstructure in these components. Therefore, understanding the heat transfer phenomenon and reliably representing exposed temperature profiles in simulation frameworks are prerequisites for studying the microstructure and residual stress development during the PBF-LB/M process. This work employs a combination of experimental measurements and model development to study this phenomenon. Thermal properties of Hastelloy X were measured in the as-deposited state and used to setup finite element (FE) thermal simulations of the PBF-LB/M process. In addition, in-situ temperature evolutions near the laser tracks were measured by instrumenting thin-wall structures with K-type thermocouples in a two-stage fabrication process. The gathered data was used to calibrate uncertain modelling parameters, and ultimately, the simulation framework could closely represent the measured temperature histories. To address the high computational cost of FE thermal simulations, an adaptive-local/global multiscale modelling approach was proposed, which substantially reduced computation times without compromising the accuracy of the results. The modelling files and scripts are available in github. [Display omitted] • PBF-LB/M fabricated Hastelloy X exhibited an exothermic effect around 500 °C. • In-situ temperature peaks up to 560 °C were measured on PBF-LB/M thin-walls. • FE thermal simulations can closely represent measurements after calibration. • The adaptive-local/global approach lowers computational costs with good accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

44. Estimating the Role of Bank Flow to Stream Discharge Using a Combination of Baseflow Separation and Geochemistry

Author

Harald Hofmann

Subjects

bank return flow, Geography, Planning and Development, baseflow separation, radon, Aquatic Science, hydrological modelling, in-situ measurements, Biochemistry, Water Science and Technology

Abstract

This study investigated the role of bank return flow to two medium size rivers in southeast Queensland using a combination of hydrograph separation techniques and geochemical baseflow separations. The main aims were to provide a case study to demonstrate spatial and temporal variability in groundwater contributions to two river systems in Southeast Victoria; the Avon River and the Mitchell River. The two rivers show large spatial and temporal variations in groundwater contributions with higher percentages during low flow periods and more surface runoff during wet years. At the end of the Australian millennium drought, groundwater discharge accounted for 60% of the total flow for the Avon River and 42% for the Michell River, whereas groundwater discharge only had a minor component to the total discharge in wetter years, ∼15% for the Avon River and only 3% for the Mitchell River. Radon and chloride were used for the geochemical baseflow separation and provide a means to separate regional groundwater discharge to the rivers from bank return flow. Bank return flow accounts for 2 to 5 times higher fluxes in certain areas. Geochemistry in combination with physical hydrogeology enhances the overall understanding of groundwater connected river systems over the river length.

Published

2023

45. Variabilidad de la circulación oceánica y forzantes asociados en la plataforma continental patagónica a partir de datos in-situ y satelitales

Author

Lago, Loreley Selene and Saraceno, Martín

Subjects

CIRCULACION OCEANICA, OBSERVACIONES DIRECTAS DE VELOCIDAD, PLATAFORMA CONTINENTAL PATAGONICA, FORZANTES DINAMICOS, OCEAN CIRCULATION, DYNAMIC FORCING, IN-SITU MEASUREMENTS, DIRECT VELOCITY OBSERVATIONS, MEDICIONES IN-SITU, SATELLITE ALTIMETRY, PATAGONIA CONTINENTAL SHELF, ALTIMETRIA SATELITAL

Abstract

El Océano Atlántico Sudoccidental alberga una de las plataformas continentales más productivas, en términos biológicos, del océano mundial: la plataforma continental Patagónica. Debido a la escasez de datos in-situ, la circulación de esta extensa región se suele estudiar a partir de modelos numéricos y datos hidrográficos. En este trabajo, describimos la variabilidad de la circulación en la plataforma patagónica a partir de observaciones directas de velocidad, en conjunto con datos de altimetría satelital y otros datos in-situ como temperatura, salinidad y presión. En particular, se analizaron las mediciones a lo largo de dos secciones: una denominada Bonaerense, que coincide con una traza de la misión satelital Jason2, alrededor de 39°S, y otra denominada sur-Patagónica, a lo largo de 44.7°S. El objetivo propuesto es analizar la variabilidad de la circulación a partir de los datos in-situ y satelitales, como así también identificar los forzantes responsables de la variabilidad observada. Las velocidades resultaron principalmente barotrópicas en todos los fondeos analizados, con dirección media hacia el noreste en la sección Bonaerense, y en la sección sur-Patagónica hacia oeste-sudoeste en la plataforma interior y hacia el norte en la exterior. La variabilidad observada en la sección Bonaerense está dominada por el gradiente de presión que genera la componente del viento paralela a la costa debido a la presencia de la costa. También se observaron eventos de reversión de las corrientes que duran varios días, distribuidos en todo el registro y que responden a los cambios de dirección de la componente del viento paralela a la costa. La variabilidad de los diversos fondeos de la sección Bonaerense es similar, lo cual permitió estimar el transporte de volumen a partir de las observaciones directas de velocidad y los datos de presión. Más aún, como la variabilidad del transporte in-situ y de la altura del mar del mareógrafo más cercano coinciden, se extendió la serie de transporte a más de 50 años. En el fondeo de la sección sur-Patagónica, las mediciones de velocidad muestran que la corriente de Malvinas afecta las corrientes de plataforma en escala estacional. Mientras que el viento impacta en las corrientes en escalas temporales intra-estacionales y su efecto en la plataforma exterior es menor que en la interior. Finalmente, se identificaron importantes variaciones intra-estacionales en las migraciones nictimerales de zooplancton en los datos de la sección sur-Patagónica. The Southwestern Atlantic Ocean houses one of the most biologically productive continental shelves of the world ocean: the Patagonia continental shelf. Due to the scarce availability of in-situ measurements, the circulation of this vast region is usually studied from hydrographic data and numerical models. In this study, we describe the variability of the Patagonia shelf circulation from direct velocity observations, along with satellite data and other in-situ measurements like temperature, salinity and pressure. Particularly, we analyzed the in-situ data collected along 2 sections: the Bonaerense section, that tally with a satellite track from the Jason-2 mission around 39oS, and the south-Patagonic section, along de 44.7oS. The objective proposed is to analyze the variability of the circulation in the continental shelf from the in-situ and satellite data available, in addition to identify its main forcing. Direct velocities from the in-situ measurements are mostly barotropic, and flow on average towards the northeast in the Bonaerense section, and towards the west-southwest in the inner shelf of the south-Patagonic section and towards the north in the outer shelf of the latter. The variability observed in the Bonaerense section is mostly attributable to the pressure gradient generated by the along-shore wind stress because of the presence of the coast. The velocities also show reversal events that last several days and are distributed throughout the record. These reversals are related to changes in the direction of the along-shore wind stress. The uniformity observed in the along-shore circulation throughout the Bonaerense section enable the estimation of the along-shore transport across this section using the direct velocity observations and the pressure measurements. Furthermore, the similarity between the transport inferred from the direct velocity observations and the sea level from the closest tide gauge allowed the extension of the along-shore transport to the complete measurement period of the tide gauge: 50 years. In the south-Patagonic section, the velocity measurements show that the Malvinas Current affects the outer shelf circulation mostly in a seasonal time scale. And while the wind stress has an impact on the intra-seasonal time scale, its effect is higher closer to the coast. Finally, we detected notable intra-seasonal variations in the vertical migrations of the zooplankton,inferred from the missing values of the direct velocity observations of the south-patagonic section. Fil: Lago, Loreley Selene. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina.

Published

2022

46. External walls energy renovation technology based on an improved temperature based method

Author

Domazetović, Mihaela, Krstić, Hrvoje, Dolaček Alduk, Zlata, and Marović, Ivan

Subjects

savings analysis, thermal transmittance (U-value), cost analysis, non-destructive methods, Temperature Based Method (TBM), external walls, in-situ measurements, building technology renovation of external walls, mathematical model

Abstract

In situ nerazorne metode vrlo su korisne za određivanje stvarnih toplinskih svojstava građevnih dijelova postojećih zgrada, posebice jer vrijednosti utvrđene mjerenjem na terenu u stvarnim uvjetima mogu značajno varirati od teorijskih vrijednosti. Zbog uočenih ograničenja standardiziranih metoda, razvijaju se nove metode s ciljem poboljšanja točnosti i pouzdane procjene in situ mjerenja. Osnovna ideja je pronaći brzu, jednostavnu i jeftinu metodu mjerenja te definirati točnost i uvjete primjene iste. Detaljnim i iscrpnim pregledom stanja područja in situ ispitivanja koeficijenta prolaska topline (U vrijednosti) vanjskih zidova nerazornim metodama, uočene su značajne prednosti temperaturne metode u odnosu na standardizirane metode poput brzine provođenja mjerenja, jednostavnosti obrade podataka i smanjenih troškova ispitivanja. Međutim pokazalo se kako nedostaju smjernice za provođenje ispitivanja te ispitivanja na različitim vrstama građevnih elemenata i u različitim uvjetima kako bi se definirala ograničenja, uklonili mogući negativni utjecaji i donijeli detaljni zaključci o mogućnosti pouzdane procjene U vrijednosti ovom metodom.U doktorskoj disertaciji istražena je mogućnost primjene temperaturne metode za ispitivanje koeficijenta prolaska topline (U vrijednosti) vanjskih zidova in situ. S ciljem proširenja spoznaja o pouzdanosti mjerenja i poboljšanja pouzdanosti mjerenja temperaturnom metodom provedeno je eksperimentalno i numeričko istraživanje. Eksperimentalna ispitivanja provedena su na 18 modela zidova od različitih zidnih elemenata. Na temelju rezultata provedenih eksperimentalnih ispitivanja u različitim temperaturnim uvjetima i numeričkih simulacija prijenosa topline provedena je analiza utjecaja različitih parametara na rezultate ispitivanja i analiza ušteda koje je moguće ostvariti primjenom temperaturne metode za određivanje U vrijednosti na troškovima obnove i tijekom razdoblja uporabe zgrada izborom ekonomski opravdanih tehnologija obnove vanjskih zidova. Također, na temelju prikazanih eksperimentalnih rezultata predloženi su pojednostavljeni matematički modeli za predviđanje U vrijednosti vanjskih zidova temperaturnom metodom. Kako bi se osigurala šira praktična primjena temperaturne metode, na temelju prikazanih rezultata i analize predložene su detaljne smjernice kojih bi se trebalo pridržavati prilikom provođenja ispitivanja temperaturnom metodom., In-situ non-destructive methods are very useful for determining the actual thermal performance of building elements of existing buildings, especially since the values determined in situ in real conditions can significantly vary from theoretical values. Due to the observed limitations of standardized methods, new methods are being developed with the aim of improving the accuracy and reliability of in situ measurements. The basic idea is to find a quick, simple, and inexpensive method and to define the accuracy and conditions of its application. A detailed and comprehensive literature review of current experimental in-situ non-destructive approaches used to determine the thermal transmittance (U-value) of walls, revealed significant advantages of recently proposed Temperature Based Method (TBM) over standardized methods such as measurement duration, simple data processing and reduced measurement costs. However, detailed guidelines for conducting in situ measurement using TBM are still missing as well as further testing on different types of building elements in different conditions to minimise all possible negative impacts and to determine all parameters affecting the accuracy of measurement.In the doctoral dissertation, the possibility of applying the TBM for in situ measurement of U-value of external walls was investigated. To improve the reliability of the TBM for in situ measurement of U-value, experimental and numerical research was conducted. For this purpose, 18 different types of external walls were experimentally investigated. Based on the experimental results performed in different thermal conditions and numeric simulations of the heat transfer, the analysis of the impact of various parameters on the results of the experiment was done. Savings analysis on the reconstruction expenses and for the period of the use of buildings that can be achieved by choosing appropriate and cost-effective building technology for renovation of external walls was done by using U-values determined by temperature based method. To provide a wider practical application of the TBM, detailed guidelines for conducting in situ measurements with TBM have been proposed based on the presented results and analysis.

Published

2022

47. Life on the edge: Adaptations of Posidonia oceanica to hypersaline conditions in a Mediterranean lagoon system.

Author

Mancuso, F.P., Bernardeau-Esteller, J., Spinelli, M., Sarà, G., Ruiz, J.M., Calvo, S., and Tomasello, A.

Subjects

*POSIDONIA, *POSIDONIA oceanica, *LAGOONS, *ECOLOGICAL forecasting, *STRESS management, LEAF growth

Abstract

Hypersaline stress is a major stressor in semi-enclosed coastal lagoons, affecting the distribution and survival of key foundation species. In this study, we investigated how Posidonia oceanica meadows responded physiologically and morphologically to different salinity concentrations both in-situ , across a natural saline gradient occurring inside the lagoon system, and in a mesocosm experiment. Leaf water relations, organic osmolytes, photosynthesis, respiration, Chlorophyll- a fluorescence, pigments content, and leaf growth were studied in P. oceanica from three different sites within the Stagnone of Marsala lagoon, as well as after exposing P. oceanica to a salinity level of 46 psu in a 30-day mesocosm experiment. Overall, we show that P. oceanica has evolved osmolar regulatory strategies and photosynthetic plasticity, allowing these meadows to cope with large salinity fluctuations (38 – 51.45 PSU). Our findings contribute to a better understanding of seagrass ecophysiological adaptation to extreme environmental conditions, as well as the importance of these populations serving as an experimental model at the Mediterranean scale for more comprehensive forecasting and management of environmental stress in these marine foundation species in an era of rapid environmental change. • A field and long-term mesocosm study on P. oceanica under salinity stress was done. • P. oceanica uses osmolar strategies and photosynthetic plasticity to to cope with salinity fluctuations. • Our observations may aid in forecasting the effects of environmental change on P. oceanica. [ABSTRACT FROM AUTHOR]

Published

2023

48. Sediment oxygen consumption: Role in the global marine carbon cycle

Author

Bo Barker Jørgensen, Frank Wenzhöfer, Matthias Egger, and Ronnie Nøhr Glud

Subjects

NUTRIENT FLUXES, DEEP-SEA SEDIMENTS, Global budget, IN-SITU MEASUREMENTS, DIFFUSIVE BOUNDARY-LAYER, Total oxygen uptake, EQUATORIAL PACIFIC, BENTHIC PRIMARY PRODUCTION, SOLUTE EXCHANGE, Database, Diffusive oxygen uptake, Organic carbon mineralization, REACTION-RATES, BALTIC SEA, General Earth and Planetary Sciences, PARTICULATE ORGANIC-CARBON, Benthic fauna

Abstract

The seabed plays a key role in the marine carbon cycle as a) the terminal location of aerobic oxidation of organic matter, b) the greatest anaerobic bioreactor, and c) the greatest repository for reactive organic carbon on Earth. We compiled data on the oxygen uptake of marine sediments with the objective to understand the constraints on mineralization rates of deposited organic matter and their relation to key environmental parameters. The compiled database includes nearly 4000 O 2 uptake data and is available as supplementary material. It includes also information on bottom water O 2 concentration, O 2 penetration depth, geographic position, water depth, and full information on the data sources. We present the different in situ and ex situ approaches to measure the total oxygen uptake (TOU) and the diffusive oxygen uptake (DOU) of sediments and discuss their robustness towards methodological errors and statistical uncertainty. We discuss O 2 transport through the benthic and diffusive boundary layers, the diffusion- and fauna-mediated O 2 uptake, and the coupling of aerobic respiration to anaerobic processes. Five regional examples are presented to illustrate the diversity of the seabed: Eutrophic seas, oxygen minimum zones, abyssal plains, mid-oceanic gyres, and hadal trenches. A multiple correlation analysis shows that seabed O 2 uptake is primarily controlled by ocean depth and sea surface primary productivity. The O 2 penetration depth scales with the DOU according to a power law that breaks down under the abyssal ocean gyres. The developed multiple correlation model was used to draw a global map of seabed O 2 uptake rates. Respiratory coefficients, differentiated for depth regions of the ocean, were used to convert the global O 2 uptake to organic carbon oxidation. The resulting global budget shows an oxidation of 212 Tmol C yr −1 in marine sediments with a 5-95% confidence interval of 175-260 Tmol C yr −1. A comparison with the global flux of particulate organic carbon (POC) from photic surface waters to the deep sea, determined from multiple sediment trap studies, suggests a deficit in the sedimentation flux at 2000 m water depth of about 70% relative to the carbon turnover in the underlying seabed. At the ocean margins, the flux of organic carbon from rivers and from vegetated coastal ecosystems contributes greatly to the budget and may even exceed the phytoplankton production on the inner continental shelf.

Published

2022

49. Microstructure of vanadium micro-alloyed steels for automotive applications

Author

Ioannidou, C., Offerman, S.E., van Well, A.A., and Delft University of Technology

Subjects

vanadium micro-alloyed steel, Small-Angle Neutron Scattering, Neutron Diffraction, in-situ measurements, Precipitation Kinetics, phase-transformation kinetics

Abstract

The focus of the present work is on the micro-alloying element vanadium, which is well known for providing precipitation strengthening to steels and which has, therefore, attracted a lot of interest the last decades. Vanadium carbide precipitation can take place in the migrating austenite/ferrite interface during the austenite-to-ferrite phase transformation, i.e. interphase precipitation, and in ferrite. Due to the beneficial contribution of the vanadium carbides to the mechanical properties of the steel and the necessity to make optimum use of vanadium, it is critical to understand and quantify the vanadium carbide precipitation and its interaction with the austenite-to-ferrite phase transformation. We study the precipitation kinetics of vanadium carbides and its interaction with the phase transformation kinetics in vanadium micro-alloyed steels that differ in vanadium and carbon concentrations and that have undergone different isothermal annealing treatments. In Chapter 1, the introduction to the research topic and the scope of this thesis are described. The novelty of our research is the use of advanced neutron scattering techniques i.e. Neutron Diffraction and Small-angle Neutron Scattering (SANS), coupled to Atom Probe Tomography (APT) and Transmission Electron Microscopy (TEM), to study model vanadium micro-alloyed steels during heat-treatments. The combination of neutron diffraction and SANS to study, simultaneously and in-situ, the interaction between the phase-transformation and precipitation kinetics is unique, as is the furnace that is designed and developed for these in-situ measurements. The results provide fundamental insight into the role of vanadium on the phase-transformation and precipitation kinetics, which is deemed essential for the development of micro-alloyed steels with reduced amounts of alloying elements without compromising properties. In Chapter 2, the vanadium carbide precipitation kinetics and its interaction with the phase transformation kinetics is investigated. Two micro-alloyed steels that differ in vanadium and carbon concentrations by a factor of two, but have the same vanadium-to-carbon atomic ratio of 1:1 are studied. Dilatometry is used for heat-treating the specimens and studying the phase-transformation kinetics during isothermal annealing at 900 °C, 750 °C and 650 °C for up to 10 h. Samples annealed for different holding times are used for ex-situ SANS, TEM and APT to study the precipitation kinetics. Vanadium carbide precipitation is only observed during or after the austenite-to-ferrite phase transformation at 650 °C and not during annealing at 900 °C and 750 °C. The precipitate volume fraction and mean radius continuously increase as the holding time increases, while the precipitate number density starts to decrease after 20 min, which corresponds to the time at which the phase transformation has finished. This indicates that nucleation and growth are dominant during the first 20 min, while later precipitate growth and coarsening take place. TEM indicates the presence of spherical/slightly ellipsoidal precipitates in all steels after annealing at 650 °C and APT shows gradual changes in the precipitate chemical composition during annealing at 650 °C, which finally reaches a 1:1 atomic ratio of vanadium-to-carbon in the core of the precipitates after 10 h.Chapter 3 introduces a custom-made furnace designed and built by our group at TU Delft. It is able to facilitate in-situ and simultaneous neutron diffraction and SANS measurements during heat-treatments of metals. In-situ and simultaneous studies on phase-transformation and precipitation kinetics are necessary in order to gain an in-depth understanding of the nucleation and growth of precipitates in relation to the evolution of austenite decomposition at high temperatures. Precipitation, occurring during solid-state phase transformations in micro-alloyed steels, is generally studied through TEM, APT and ex-situ SANS measurements. The advantage of SANS over the other two characterization techniques is that it allows for the quantitative determination of size distribution, volume fraction, and number density of a statistically significant number of precipitates within the resulting iron matrix at room temperature. However, individual ex-situ SANS measurements do not provide information regarding the correlation between interphase precipitation and phase transformations. The presented furnace is, thus, developed for in-situ studies in which SANS measurements can be performed simultaneously to neutron diffraction measurements during typical high-temperature thermal treatments for steels. The furnace is capable of carrying out thermal treatments involving fast heating and cooling as well as high operation temperatures (up to 1200 °C) for a long period of time with accurate temperature control in a protective atmosphere and in a magnetic field of up to 1.5 T. The characteristics of this furnace give the possibility of developing new research studies for better insight of the relationship between phase-transformation and precipitation kinetics in steels and also in other types of materials containing nano-scale microstructural features.In Chapter 4, in-situ SANS is used to determine the time evolution of the chemical composition of precipitates at 650 °C and 700 °C in three micro-alloyed steels with different vanadium and carbon concentrations. The evolution of the ratio of the nuclear to magnetic SANS component is used for this analysis. The samples are heat-treated in the furnace presented in Chapter 3. Precipitates with a distribution of sub-stoichiometric carbon-to-metal ratios in all steels are detected. The precipitates have a high iron content at the early stages of annealing, which is gradually being substituted by vanadium during isothermal holding. Eventually a plateau in the composition of the precipitate phase is reached. Faster changes in the precipitate chemical composition are observed at the higher temperature in all steels. We found that the addition of vanadium and carbon to the steel has an accelerating effect on the evolution of the precipitate composition. Addition of vanadium to the nominal composition of the steel increases the concentration of vanadium in the precipitates, reduces the iron concentration and leads to a smaller carbon-to-metal ratio. APT measurements prove the presence of precipitates with a distribution of carbon-to-metal ratios, ranging from 0.75 to 1, after 10 h of annealing at 650 °C or 700 °C in all studied steels.In Chapter 5, in-situ neutron diffraction and SANS are employed for the first time simultaneously in order to reveal the interaction between the austenite-to-ferrite phase-transformation and the precipitation kinetics in-situ in vanadium micro-alloyed steels. The neutron scattering measurements are performed in three steels with different vanadium and carbon concentrations during isothermal annealing treatments at 650 °C and 700 °C for 10 h. The furnace introduced in Chapter 3 is used for the heat treatments. The austenite-to-ferrite phase-transformation and precipitation kinetics are quantified and the interaction between these two phenomena is explained. We show that the phase transformation is completed during the 10 h annealing treatment in all cases and that it is faster at 650 °C than at 700 °C for all alloys. Our analysis shows that additions of vanadium and carbon to the steel composition cause a retardation of the phase transformation and the effect of each element is explained through its contribution to the Gibbs free energy dissipation. The phase transformation is found to initiate the vanadium carbide precipitation. The presence of ellipsoidal precipitates is confirmed by TEM, contributing to the SANS data analysis. Larger and fewer precipitates are detected at the higher temperature in all three steels, and a larger number density of precipitates is detected in the steel with higher concentrations of vanadium and carbon. The effect of the precipitation kinetics to the phase-transformation kinetics is also discussed. An important outcome is that the external magnetic field applied during the experiments, necessary for the SANS measurements, causes a delay in the onset and time evolution of the phase transformation and consequently on the precipitation kinetics.

Published

2022

50. Retrieval of vertical mass concentration distributions

Author

Wang, Longlong, Gosar, Mateja, Miler, Miloš, Vaupotič, Janja, Drinovec, Luka, Močnik, Griša, Eichinger, William, Bergant, Klemen, Stanič, Samo, and Gregorič, Asta

Subjects

aerosol vertical distributions, aerosol identification, respiratory system, lidar remote sensing, in-situ measurements, complex mixtures, udc:528, valley air pollution

Abstract

Aerosol vertical profiles are valuable inputs for the evaluation of aerosol transport models, in order to improve the understanding of aerosol pollution ventilation processes which drive the dispersion of pollutants in mountainous regions. With the aim of providing high-accuracy vertical distributions of particle mass concentration for the study of aerosol dispersion in small-scale valleys, vertical profiles of aerosol mass concentration for aerosols from different sources (including Saharan dust and local biomass burning events) were investigated over the Vipava valley, Slovenia, a representative hot-spot for complex mixtures of different aerosol types of both anthropogenic and natural origin. The analysis was based on datasets taken between 1–30 April 2016. In-situ measurements of aerosol size, absorption, and mass concentration were combined with lidar remote sensing, where vertical profiles of aerosol concentration were retrieved. Aerosol samples were characterized by SEM-EDX, to obtain aerosol morphology and chemical composition. Two cases with expected dominant presence of different specific aerosol types (mineral dust and biomass-burning aerosols) show significantly different aerosol properties and distributions within the valley. In the mineral dust case, we observed a decrease of the elevated aerosol layer height and subsequent spreading of mineral dust within the valley, while in the biomass-burning case we observed the lifting of aerosols above the planetary boundary layer (PBL). All uncertainties of size and assumed optical properties, combined, amount to the total uncertainty of aerosol mass concentrations below 30% within the valley. We have also identified the most indicative in-situ parameters for identification of aerosol type.

Published

2022