Your search keyword '"Armon, Moshe"' showing total 4 results

1. A mechanistic approach for interpreting hydroclimate from halite‐bearing sediments.

Author

Sirota, Ido, Armon, Moshe, Ben Dor, Yoav, Morin, Efrat, Lensky, Nadav G., and Enzel, Yehouda

Subjects

*HYDROLOGIC cycle, *SALT, *BODIES of water, *SEA level, *SEDIMENTS, *PALEOHYDROLOGY

Abstract

Establishing accurate palaeo‐hydroclimatic reconstructions from lacustrine and marine archives is a long‐standing challenge in palaeoenvironment studies. Closed‐basin evaporites, and especially halite, record episodes of extremely arid conditions during rapid climate change. However, the complex limnological behaviour of deep hypersaline water bodies and the stochastic nature of the hydroclimatic regime and its variations limit detailed palaeo‐hydroclimatic interpretations from such records. Therefore, a mass‐balance model was developed to explore hydrology–limnology–sedimentology relationships in hypersaline environments under both deterministic and stochastic approaches that generates synthetic halite–mud sequences. Applying the model to the Holocene Dead Sea halites yields novel insights into palaeoenvironmental conditions in the Levant. The deterministic framework indicates that: (i) under a series of similar hydroclimatic cycles, the thickness of each subsequent halite interval decreases, due to the depletion of dissolved‐ions storage in the brine; (ii) halite deposition requires lake levels to drop below the minimal lake level of the preceding cycle; (iii) the time interval between halite deposition and the hydrological minimum is increasingly longer in subsequent cycles. Thus, counter‐intuitively, halite deposition mostly takes place as water discharge increases, providing that the water balance is still negative. The stochastic approach produced random sequences comparable to the observed Dead Sea sedimentary record. It demonstrates that some hydrological minima are not represented by halite deposition at all. Furthermore, the thickness and number of halite beds at each hydrological cycle vary substantially, depending on the specific hydrological conditions realized. Finally, these results imply that the major Dead Sea level drop at the pre‐Holocene deglaciation (ca 14 ka bp), previously assumed to be a record minimum, could not have been as pronounced as suggested, and must have been milder than the subsequent drop at the early Holocene (ca 11–10 ka bp). [ABSTRACT FROM AUTHOR]

Published

2023

2. Sediment Residence Times in Large Rivers Quantified Using a Cosmogenic Nuclides Based Transport Model and Implications for Buffering of Continental Erosion Signals.

Author

Ben‐Israel, Michal, Armon, Moshe, and Matmon, Ari

Subjects

COSMOGENIC nuclides, SEDIMENT transport, SEDIMENTATION & deposition, SEDIMENTS, SURFACE of the earth, FLUVIAL geomorphology, EROSION

Abstract

The weathering of continental surfaces and the transport of sediments via rivers into the oceans is an integral part of the dynamic processes that shape the Earth's surface. To understand how tectonic and climatic forcings control regional rates of weathering, we must be able to identify their effects on sedimentary archives over geologic timescales. Cosmogenic nuclides are a valuable tool to study rates of surface processes and have long been applied in fluvial systems to quantify basin‐wide erosion rates. However, in large rivers, continual processes of erosion and deposition during sediment transport make it difficult to constrain how long sediments spend within the fluvial system. In this study, we examine the role of rivers in buffering erosional signals by constraining the timescales of fluvial transport in large rivers across the world. We apply a stochastic numerical model based on measurements of cosmogenic nuclides concentrations and calculate sediment residence times of 104–105 years in large rivers. These timescales are equal to or longer than climatic cycles, implying that changes to rates of erosion brought on by climatic variations are buffered during transport in large rivers and may not be recognizable in the sedimentary record. Plain Language Summary: Large rivers are the most effective agent for transporting sediment from the weathering continents into the oceans, with the world's biggest rivers draining nearly half of the continental surface. In this work, we calculate the time sediment spends in large rivers between weathering and deposition in four large rivers across the world. We do this by simulating the processes of sediment erosion and deposition in rivers and applying this model to new and existing data. The results of this model show that the time it takes for sand to be eroded from the source rock and transported down the river is tens to hundreds of thousands of years. These extended timescales mean that sediment transport in large rivers buffers the effect of climatic fluctuations on weathering rates. This finding can explain how seemingly contradictory evidence of climatic variations impact erosion rates, while products of erosion measured at the oceans show no significant changes during these times. Key Points: We constructed a numerical model simulating sediment transport dynamics in large‐scale fluvial systems constrained by cosmogenic nuclidesExamining data from four large rivers across the world, we constrain sediment residence time in large riversEstimated residence times of sediments in four large rivers across the world range 104–105 yr [ABSTRACT FROM AUTHOR]

Published

2022

3. Hydroclimatic variability of opposing Late Pleistocene climates in the Levant revealed by deep Dead Sea sediments.

Author

Ben Dor, Yoav, Marra, Francesco, Armon, Moshe, Enzel, Yehouda, Brauer, Achim, Schwab, Markus Julius, and Morin, Efrat

Subjects

PLEISTOCENE Epoch, TIME series analysis, CLIMATE change, WATER supply, FLOODS, SEDIMENTS

Abstract

Annual and decadal-scale hydroclimatic variability describes key characteristics that are embedded into climate in situ and is of prime importance in subtropical regions. The study of hydroclimatic variability is therefore crucial to understand its manifestation and implications for climate derivatives such as hydrological phenomena and water availability. However, the study of this variability from modern records is limited due to their relatively short span, whereas model simulations relying on modern dynamics could misrepresent some of its aspects. Here we study annual to decadal hydroclimatic variability in the Levant using two sedimentary sections covering ∼ 700 years each, from the depocenter of the Dead Sea, which has been continuously recording environmental conditions since the Pleistocene. We focus on two series of annually deposited laminated intervals (i.e., varves) that represent two episodes of opposing mean climates, deposited during MIS2 lake-level rise and fall at ∼ 27 and 18 ka, respectively. These two series comprise alternations of authigenic aragonite that precipitated during summer and flood-borne detrital laminae deposited by winter floods. Within this record, aragonite laminae form a proxy of annual inflow and the extent of epilimnion dilution, whereas detrital laminae are comprised of sub-laminae deposited by individual flooding events. The two series depict distinct characteristics with increased mean and variance of annual inflow and flood frequency during "wetter", with respect to the relatively "dryer", conditions, reflected by opposite lake-level changes. In addition, decades of intense flood frequency (clusters) are identified, reflecting the in situ impact of shifting centennial-scale climate regimes, which are particularly pronounced during wetter conditions. The combined application of multiple time series analyses suggests that the studied episodes are characterized by weak and non-significant cyclical components of sub-decadal frequencies. The interpretation of these observations using modern synoptic-scale hydroclimatology suggests that Pleistocene climate changes resulted in shifts in the dominance of the key synoptic systems that govern rainfall, annual inflow and flood frequency in the eastern Mediterranean Sea over centennial timescales. [ABSTRACT FROM AUTHOR]

Published

2021

4. Frequency of torrential rainstorms during a regional late Holocene drought inferred from a Dead Sea sediment record.

Author

Schwab, Markus, Ahlborn, Marieke, Armon, Moshe, Dor, Yoav Ben, Neugebauer, Ina, Tjallingii, Rik, Shoqeir, Jawad Hasan, Morin, Efrat, Enzel, Yehouda, Brauer, Achim, and Team, Palex Scientific

Subjects

*RAINSTORMS, *DROUGHT management, *DROUGHTS, *SEDIMENTS, *SEAS, *RECORDS, *DEAD

Published

2018