Machine Learning With Data Assimilation and Uncertainty Quantification for Dynamical Systems:A Review

Data assimilation(DA)and uncertainty quantification(UQ)are extensively used in analysing and reducing error propagation in high-dimensional spatial-temporal dynamics.Typical applications span from computational fluid dynamics(CFD)to geoscience and climate systems.Recently,much effort has been given in combining DA,UQ and machine learning(ML)techniques.These research efforts seek to address some critical challenges in high-dimensional dynamical systems,including but not limited to dynamical system identification,reduced order surrogate modelling,error covariance specification and model error correction.A large number of developed techniques and methodologies exhibit a broad applicability across numerous domains,resulting in the necessity for a comprehensive guide.This paper provides the first overview of state-of-the-art researches in this interdisciplinary field,covering a wide range of applications.This review is aimed at ML scientists who attempt to apply DA and UQ techniques to improve the accuracy and the interpretability of their models,but also at DA and UQ experts who intend to integrate cutting-edge ML approaches to their systems.Therefore,this article has a special focus on how ML methods can overcome the existing limits of DA and UQ,and vice versa.Some exciting perspectives of this rapidly developing research field are also discussed.Index Terms-Data assimilation(DA),deep learning,machine learning(ML),reduced-order-modelling,uncertainty quantification(UQ).

Moisture-Induced Non-Equilibrium Phase Segregation in Triple Cation Mixed Halide Perovskite Monitored by In Situ Characterization Techniques and Solid-State NMR

Environmental stability is a major bottleneck of perovskite solar cells.Only a handful of studies are investigating the effect of moisture on the structural degradation of the absorber.They mostly rely on ex situ experiments and on completely degraded samples,which restrict the assessment on initial and final stage.By combining in situ X-ray diffraction under controlled 85%relative humidity,and live observations of the water-induced degradation using liquid-cell transmission electron microscopy,we reveal two competitive degradation paths leading on one hand to the decomposition of state-of-theart mixed cation/anion(Cs_(0.05)(MA_(0.17)FA_(0.83))_(0.95)Pb(Br_(0.17)I_(0.83))_(3)(CsMAFA)into PbI_(2) through a dissolution/recrystallization mechanism and,on the other hand,to a non-equilibrium phase segregation leading to CsPb_(2)Br_(5) and a Cesium-poor/iodide-rich Cs_(0.05)-x(MA_(0.17)FA_(0.83))_(0.95)Pb(Br_(0.17-2y)I_(0.83)+2y)_(3) perovskite.This degradation mechanism is corroborated at atomic-scale resolution through solid-state ^(1)H and ^(133)Cs NMR analysis.Exposure to moisture leads to a film containing important heterogeneities in terms of morphology,photoluminescence intensities,and lifetimes.Our results provide new insights and consensus that complex perovskite compositions,though very performant as champion devices,are comparatively metastable,a trait that limits the chances to achieve long-term stability.

基于能量最小化准则的RPV堆芯筒体段断裂安全评估

压水堆核电站反应堆压力容器(RPV)辐照脆化问题是制约其长期安全服役的主要因素之一,如何精确预测其断裂行为是行业的技术难点。首先研究了一种基于能量的新型脆性断裂准则(G_(p)准则),论述了该准则可考虑裂纹尖端的拘束效应和卸载效应;然后采用标准拉伸试样测试了材料拉伸性能,基于CT试样测试获得其断裂临界载荷,进行断裂参量计算、断裂韧度预测及断裂评价准则等内容研究;最后针对某RPV堆芯筒体段进行工程案例示范应用。研究结果表明,初步建立的G_(p)断裂评价准则可进行工程实际应用,在工程案例输入瞬态载荷下RPV堆芯结构是安全的。

热预应变对反应堆压力容器材料断裂行为影响研究

压水堆核电站反应堆压力容器(RPV)辐照脆化问题是制约其长期安全服役的主要因素,现有的美国ASME和法国RCC-M规范尚未充分考虑RPV用钢(铁素体材料)的热预应力(WPS)对断裂评价的有益影响。针对某RPV材料(16 MND 5),采用标准CT试样进行室温加载(L)、保持载荷降低测试温度(C),最后加载直至断裂(F)的测试方案(LCF的测试过程)。试验结果表明,在LCF的最后低温断裂阶段,RPV材料实际断裂韧度为基于RCC-M规范预测结果的两倍左右,也明显高于主曲线预测的断裂失效概率为95%对应的材料断裂韧度。因此,在RPV寿期末的脆性断裂评价中,考虑WPS效应会显著提高其安全性能评估裕量。

压水堆核电厂稳压器波动管热分层分析关键技术探讨

压水堆核电厂稳压器波动管(以下简称“波动管”)存在冷热流体分层的现象,影响核电厂的安全运行。针对波动管热分层运行工况存在不确定性的问题,鲜有基于核电厂真实监测数据的分析研究;对于存在热分层的实际运行瞬态,尚缺乏有效的基于设计瞬态参数的包络方法;同时,对于疲劳损伤较为显著的情况,当前基于疲劳裂纹萌生准则的评定方法存在难以满足长寿期安全运行需求的问题。针对上述技术现状,通过调研国内外学者在波动管热分层研究方面的工作,对有限元数值仿真中的网格划分、材料性能设定、边界条件选择、热分层流动仿真和结构应力响应分析技术等内容进行了探讨。同时,对国内某大型压水堆核电厂真实的运行监测数据进行了分析,梳理了基于设计瞬态信息的疲劳损伤包络分析准则和采用疲劳裂纹扩展的损伤容限分析方法。

一种基于能量最小化的断裂准则及其在ABAQUS软件中的应用

研究法国电力公司研发部提出的一个新型的脆性断裂能量准则——G_(p)方法论,该理论将断裂力学和损伤力学相结合,基于能量最小化原则,为判断结构中裂纹是否扩展提供了理论依据。同时,为推动G_(p)方法论的工程应用,基于标准CT50试样,研究了在通用有限元软件ABAQUS中应用G_(p)断裂评估准则的方法。

基于纳米流体的可凝气体直接抽提CO2再生实验研究

为进一步降低化学吸收过程中吸收剂的再生能耗,提出了基于纳米流体吸收剂的可凝气体直接抽提CO2再生工艺,制备了基于SiO2、TiO2、γ-Al2O3纳米颗粒和乙醇胺(MEA)溶液的纳米流体吸收剂,并选定戊烷、己烷和环己烷作为吹扫气,研究了基于纳米流体吸收剂的可凝气体直接抽提CO2再生性能,并对再生速率、循环负荷和再生能耗等参数进行了分析。结果表明:纳米流体吸收剂样品具备良好的稳定性;相比于传统再生方式,戊烷吹扫具有最优的再生效果,可降低超过40%的再生能耗。

Three‐terminal perovskite/integratedbackcontactsilicon tandem solar cells under low light intensity conditions

The current climate and energy crisis urgently needs solar cells with efficiencies above the 29% single junction efficiency bottleneck.Silicon/perovskite tandem solar cells are a solution,which is attracting much attention.While silicon/perovskite tandem cells in 2-terminal and 4-terminal configurations are well documented,the three-terminal concept is still in its infancy.It has significant advantages under low light intensities as opposed to concentrated sunlight,which is the critical factor in designing tandem solar cells for low-cost terrestrial applications.This study pre-sents novel studies of the sub-cell performance of the first three-terminal perovskite/silicon selective band offset barrier tandem solar cells fabricated in an ongoing research project.This study focuses on short circuit current and operating voltages of the subcells under light intensities of one sun and below.Lifetime studies show that the perovskite bulk carrier lifetime is insensitive to illumination,while the silicon cell's lifetime decreases with decreasing light intensity.The combination of perovskite and silicon in the 3T perovskite-silicon tandem therefore reduces the sensitivity of V_(OC) to light intensity and maintains a relatively higher V_(OC) down to low light intensities,whereas silicon single-junction cells show a marked decrease.This technological advantage is proposed as a novel advantage of three-terminal perovkite/silicon solar cells for low light intensities of one sun or less.

Organic aerosol molecular composition and gas–particle partitioning coefficients at a Mediterranean site(Corsica)

Molecular speciation of atmospheric organic matter was investigated during a short summer field campaign performed in a citrus fruit field in northern Corsica(June 2011). Aimedat assessing the performance on the field of newly developed analytical protocols, this work focuses on the molecular composition of both gas and particulate phases and provides an insight into partitioning behavior of the semi-volatile oxygenated fraction. Limonene ozonolysis tracers were specifically searched for, according to gas chromatography–mass spectrometry(GC–MS) data previously recorded for smog chamber experiments. A screening of other oxygenated species present in the field atmosphere was also performed. About sixty polar molecules were positively or tentatively identified in gas and/or particle phases. These molecules comprise a wide range of branched and linear, mono and di-carbonyls(C_3–C7),mono and di-carboxylic acids(C_3–C_18), and compounds bearing up to three functionalities.Among these compounds, some can be specifically attributed to limonene oxidation and others can be related to α- or β-pinene oxidation. This provides an original snapshot of the organic matter composition at a Mediterranean site in summer. Furthermore, for compounds identified and quantified in both gaseous and particulate phases, an experimental gas/particle partitioning coefficient was determined. Several volatile products, which are not expected in the particulate phase assuming thermodynamic equilibrium, were nonetheless present in significant concentrations. Hypotheses are proposed to explain these observations, such as the possible aerosol viscosity that could hinder the theoretical equilibrium to be rapidly reached.

Characterization of random stress fields obtained from polycrystalline aggregate calculations using multi-scale stochastic finite elements

The spatial variability of stress fields resulting from polycrystalline aggregate calculations involving random grain geometry and crystal orientations is investigated. A periodogram-based method is proposed to identify the properties of homogeneous Gaussian random fields （power spectral density and related covariance structure）. Based on a set of finite element polycrystalline aggregate calculations the properties of the maximal principal stress field are identified. Two cases are considered, using either a fixed or random grain geometry. The stability of the method w.r.t the number of samples and the load level （up to 3.5% macroscopic deformation） is investigated.

Innovative Solutions in Induction Heating for Better Energy Efficiency:Presentation of ISIS Project

The Energy Climate Package is the EU response to the Global Warming Challenge.Induction heating processes can contribute to the energy saving goal:20%saving within 2020.European induction manufacturer already propose many efficient solutions at industrial scale.To improve induction devices for an always better energy efficiency,EDF R&D set up a French cooperative project called ISIS with a financial support of the French National Research Agency.Its objective is to promote induction heating as Best Available Technology(BAT)and to develop innovative solutions to increase its efficiency.The ISIS innovations concern the electroheat conversion of induction devices(auto-adaptive multi-coil power supply,low losses coils)and the recovering of fatally lost energy.This paper shows the mid-term results of this project.Firsts control algorithms were successfully tested on a 100 kW 3-coil power supply.A homogenization technique is proposed to model a multi-strand coil.A heat recovery test bench is build and equipped with a PFC control loop to fit with the production fluctuations.

Experimental characterization of the removal efficiency and energy effectiveness of central air cleaners

This study assessed six commercially available in-duct air cleaning devices which are designed to be mounted in the central ventilation system of offices or commercial buildings.The selected devices use different air cleaning technologies:mechanical filtration,electrostatic precipitation,gas filtration,ionization/cold plasma,photocatalytic oxidation(PCO)and catalysis under UV light.They were tested against particles,a mixture of volatile organic compounds containing acetone,acetaldehyde,toluene,heptane and formaldehyde,and two bio-contaminants:Aspergillus brasiliensis(fungus)and Staphylococcus epidermidis(bacteria).Two different test rigs were used.The single pass efficiency of each device was determined for three airflow rates,corresponding to face velocities ranging from 0.9 to 2.7 m/s,and two sets of temperature and humidity that are representative of indoor air conditions in wintertime and summertime.The concentration of the chal-lenge volatile organic compounds was also varied in the 30 to 100μg/m^(3)range as a way to characterize their influence on efficiency at realistic concentration levels for non-industrial buildings.Measurements of ozone and formaldehyde concentration downstream of the air cleaners were carried out to determine the emission rate of by-products into the air stream.Finally,the energy issue was addressed by measuring the electric power drawn and pressure loss of the devices.The results showed that two devices,namely a radiant catalytic ionizer and a plasma ionizer,had a very low single pass efficiency against all the challenge pollutants.The association of the plasma ionizer and the electrostatic precipitator did not produce a synergetic effect between the two technologies either,contrary to what their manufacturer claims.Finally,three of the six devices tested were effective in terms of pollutant removal,but only two had an acceptable energy effectiveness in view of their use in low or zero energy buildings.Their energy effectiveness ranged from a few thousand m^(3)/kWh for VOCs at the highest airflow rate(3600 m^(3)/h),to more than 60000 m^(3)/kWh for particles and bio-contaminants at 1200 or 1600 m^(3)/h.These results are at least one order of magnitude higher than the majority of stand-alone air cleaners.Moreover,they suggest that optimal IAQ and energy conditions can be achieved if variable air volume control methods are used to maintain indoor temperature and humidity.

Raman investigation of air-stable silicene nanosheetson an inert graphite surface

The fascinating properties of two-dimensional （2D） crystals have gainedincreasing interest for many applications. The synthesis of a 2D silicon structure,namely silicene, is attracting great interest for possible development of nextgeneration electronic devices. The main difficulty in working with siliceneremains its strong tendency to oxidation when exposed to air as a consequenceof its relatively highly buckled structure. In this work, we univocaUy identifythe Raman mode of air-stable low-buckled silicene nanosheets synthesized onhighly oriented pyrolytic graphite （HOPG） located at 542.5 cm-1. The main focusof this work is Raman spectroscopy and mapping analyses in combination withab initio calculations. Scanning tunneling microscopy images reveal the presenceof a patchwork of Si three-dimensional （3D） clusters and contiguous Si areaspresenting a honeycomb atomic arrangement, rotated by 30° with respect to theHOPG substrate underneath, with a lattice parameter of 0.41±0.02 nm and abuckling of the Si atoms of 0.05 nm. Raman analysis supports the co-existenceof 3D silicon clusters and 2D silicene. The Raman shift of low-buckled siliceneon an inert substrate has not been reported so far and it is completely differentfrom the one calculated for free-standing silicene and the ones measured forsilicene grown on Ag（111） surfaces. Our experimental results are perfectlyreproduced by our ab initio calculations of deposited silicene nanosheets. Thisleads us to conclude that the precise value of the observed Raman shift crucially depends on the strain between the silicene and the HOPG substrate.