Water Exfiltration from Bedrock: A Drastic Landslide Triggering Mechanism

Background: Anticancer chemotherapeutics have a lot of problems via conventional Drug Delivery Systems (DDSs), including non-specificity, burst release, severe side-effects, and damage to normal cells. Owing to its potential to circumventing these problems, nanotechnology has gained increasing attention in targeted tumor therapy. Chemotherapeutic drugs or genes encapsulated in nanoparticles could be used to target therapies to the tumor site in three ways: “passive”, “active”, and “smart” targeting. Objective: To summarize the mechanisms of various internal and external “smart” stimulating factors on the basis of findings from in vivo and in vitro studies. Method: A thorough search of PubMed was conducted in order to identify the majority of trials, studies and novel articles related to the subject. Results: Activated by internal triggering factors (pH, redox, enzyme, hypoxia, etc.) or external triggering factors (temperature, light of different wavelengths, ultrasound, magnetic fields, etc.), “smart” DDSs exhibit targeted delivery to the tumor site, and controlled release of chemotherapeutic drugs or genes. Conclusion: In this review article, we summarize and classify the internal and external triggering mechanism of “smart” nanoparticle-based DDSs in targeted tumor therapy, and the most recent research advances are illustrated for better understanding.

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Reliability modeling for multi-state systems with a protective device considering multiple triggering mechanism

Proceedings of the Institution of Mechanical Engineers Part O Journal of Risk and Reliability ◽

10.1177/1748006x211013325 ◽

2021 ◽

pp. 1748006X2110133

Author(s):

Xian Zhao ◽

Rong Li ◽

Yu Fan ◽

Qingan Qiu

Keyword(s):

Failure Modes ◽

Operating Time ◽

Replacement Policy ◽

Economic Losses ◽

Residual Lifetime ◽

Cumulative Number ◽

Protective Device ◽

Triggering Mechanism ◽

Safety Critical ◽

Markov Chain Imbedding

Failures of safety-critical systems may result in irretrievable economic losses and significant safety hazards, thus enhancing the reliability of safety-critical system is crucial. As applied widely in engineering fields, protective devices are commonly equipped for the systems operating in shock environment to reduce external damage, which has not been taken into consideration in existing literatures. This paper investigates the reliability of multi-state systems with competing failure patterns supported by a protective device. According to the system failure modes, state-based and shock number-based triggering mechanism of the protective device are developed. That is, the protective device is triggered once the system state or cumulative number of shocks exceeds corresponding critical thresholds respectively. After being triggered, the protective device can reduce the probability of damaging shocks for the system. The protective device fails when the number of consecutive valid shocks reaches a threshold. Based on the constructed model, a finite Markov chain imbedding approach is employed to derive reliability indices including distribution functions of system lifetime and residual lifetime, together with expected operating time of the protective device. Moreover, two age-based replacement policies together with a condition-based replacement policy are developed to accommodate different maintenance scenarios and corresponding optimal solutions are acquired. Numerical illustrations based on the application of cooling systems in engines are presented to validate the results.

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A comparative machine learning approach to identify landslide triggering factors in northern Chilean Patagonia

Landslides ◽

10.1007/s10346-021-01675-9 ◽

2021 ◽

Author(s):

Bastian Morales ◽

Elizabet Lizama ◽

Marcelo A. Somos-Valenzuela ◽

Mario Lillo-Saavedra ◽

Ningsheng Chen ◽

...

Keyword(s):

Machine Learning ◽

Learning Approach ◽

Triggering Factors ◽

Chilean Patagonia ◽

Machine Learning Approach ◽

Landslide Triggering

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Event-Triggering State and Fault Estimation for a Class of Nonlinear Systems Subject to Sensor Saturations

Sensors ◽

10.3390/s21041242 ◽

2021 ◽

Vol 21 (4) ◽

pp. 1242

Author(s):

Cong Huang ◽

Bo Shen ◽

Lei Zou ◽

Yuxuan Shen

Keyword(s):

Nonlinear Systems ◽

Difference Equations ◽

Estimation Error ◽

Upper Bounds ◽

The State ◽

Fault Estimation ◽

Triggering Mechanism ◽

Transmission Frequency ◽

Current Transmission ◽

Event Triggering

This paper is concerned with the state and fault estimation issue for nonlinear systems with sensor saturations and fault signals. For the sake of avoiding the communication burden, an event-triggering protocol is utilized to govern the transmission frequency of the measurements from the sensor to its corresponding recursive estimator. Under the event-triggering mechanism (ETM), the current transmission is released only when the relative error of measurements is bigger than a prescribed threshold. The objective of this paper is to design an event-triggering recursive state and fault estimator such that the estimation error covariances for the state and fault are both guaranteed with upper bounds and subsequently derive the gain matrices minimizing such upper bounds, relying on the solutions to a set of difference equations. Finally, two experimental examples are given to validate the effectiveness of the designed algorithm.

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Self‐healing triggering mechanism in epoxy‐based material containing microencapsulated amino‐polysiloxane

Nano Select ◽

10.1002/nano.202100091 ◽

2021 ◽

Author(s):

Sara Ferreira Da Costa ◽

Marcus Zuber ◽

Margarita Zakharova ◽

Andrey Mikhaylov ◽

Tilo Baumbach ◽

...

Keyword(s):

Self Healing ◽

Triggering Mechanism

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Model predictive control for switched systems with a novel mixed time/event-triggering mechanism

Nonlinear Analysis Hybrid Systems ◽

10.1016/j.nahs.2021.101081 ◽

2021 ◽

Vol 42 ◽

pp. 101081

Author(s):

Yiwen Qi ◽

Wenke Yu ◽

Jie Huang ◽

Yang Yu

Keyword(s):

Model Predictive Control ◽

Predictive Control ◽

Switched Systems ◽

Triggering Mechanism ◽

Event Triggering

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The effect of hydrogeological and hydrochemical dynamics on landslide triggering in the central highlands of Ethiopia

Hydrogeology Journal ◽

10.1007/s10040-020-02288-7 ◽

2021 ◽

Vol 29 (3) ◽

pp. 1239-1260

Author(s):

Tesfay Kiros Mebrahtu ◽

Andre Banning ◽

Ermias Hagos Girmay ◽

Stefan Wohnlich

Keyword(s):

Hydrostatic Pressure ◽

Groundwater Flow ◽

Volcanic Rocks ◽

Chemical Characterization ◽

Unconsolidated Sediments ◽

Ethiopian Rift ◽

Main Ethiopian Rift ◽

Groundwater Level Fluctuations ◽

Landslide Mass ◽

Landslide Triggering

AbstractThe volcanic terrain at the western margin of the Main Ethiopian Rift in the Debre Sina area is known for its slope stability problems. This report describes research on the effects of the hydrogeological and hydrochemical dynamics on landslide triggering by using converging evidence from geological, geomorphological, geophysical, hydrogeochemical and isotopic investigations. The chemical characterization indicates that shallow to intermediate aquifers cause groundwater flow into the landslide mass, influencing long-term groundwater-level fluctuations underneath the landslide and, as a consequence, its stability. The low content of total dissolved solids and the bicarbonate types (Ca–Mg–HCO3 and Ca–HCO3) of the groundwater, and the dominantly depleted isotopic signature, indicate a fast groundwater flow regime that receives a high amount of precipitation. The main causes of the landslide are the steep slope topography and the pressure formed during precipitation, which leads to an increased weight of the loose and weathered materials. The geophysical data indicate that the area is covered by unconsolidated sediments and highly decomposed and weak volcanic rocks, which are susceptible to sliding when they get moist. The heterogeneity of the geological materials and the presence of impermeable layers embodied within the highly permeable volcanic rocks can result in the build-up of hydrostatic pressure at their interface, which can trigger landslides. Intense fracturing in the tilted basalt and ignimbrite beds can also accelerate infiltration of water, resulting to the build-up of high hydrostatic pressure causing low effective normal stress in the rock mass, giving rise to landslides.

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