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  • Date:16ThursdayJanuary 2025

    Vision and AI

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    Time
    12:15 - 13:15
    Title
    Interpreting the Inner Workings of Vision Models
    Location
    Jacob Ziskind Building
    Room 1 - 1 חדר
    LecturerYossi Gandelsman
    UC Berkeley/Meta
    Organizer
    Department of Computer Science and Applied Mathematics
    Contact
    AbstractShow full text abstract about In this talk, I present an approach for interpreting the int...»
    In this talk, I present an approach for interpreting the internal computation in deep vision models. I show that these interpretations can be used to detect model bugs and to improve the performance of pre-trained deep neural networks (e.g., reducing hallucinations from image captioners and detecting and removing spurious correlations in CLIP) without any additional training. Moreover, the obtained understanding of deep representations can unlock new model capabilities (e.g., novel identity editing techniques in diffusion models and faithful image inversion in GANs). I demonstrate how to find common representations across different models (discriminative and generative) and how deep representations can be adapted at test-time to improve model generalization without any additional supervision. Finally, I discuss future work on improving the presented interpretation techniques and their application to continual model correction and scientific discovery.

    Bio: Yossi is a EECS PhD at UC Berkeley, advised by Alexei Efros, and a visiting researcher at Meta. Before that, he was a member of the perception team at Google Research (now Google-DeepMind). He completed his M.Sc. at Weizmann Institute, advised by Prof. Michal Irani. His research centers around deep learning, computer vision, and mechanistic interpretability.
    Lecture
  • Date:16ThursdayJanuary 2025

    Geometric Functional Analysis and Probability Seminar

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    Time
    13:30 - 14:30
    Title
    Free boundary problems and particle systems
    Location
    Jacob Ziskind Building
    Room 155 - חדר 155
    LecturerRami Atar
    Technion
    Organizer
    Department of Mathematics
    Contact
    AbstractShow full text abstract about Particle systems that can be described macroscopically via f...»
    Particle systems that can be described macroscopically via free boundary problems (FBP) include the $N$-branching Brownian motion (branching Brownian particles on the line with removal of the leftmost particle upon each branching), and the Atlas model (Brownian particles on the line where the leftmost particle is equipped with a positive drift). The regularity of the free boundary plays a crucial role in proving the particle system -- FBP relation, but does not hold in some natural generalizations of these models. I will describe a weak FBP formulation where control over free boundary regularity is not required in order to achieve this relation in the two cases above. I will also describe an analogous weak formulation of a ``free obstacle’' problem aimed at a branching Brownian motion with removals occurring at the most densely populated areas.

    This is partly based on joint works with Amarjit Budhiraja and with Leonid Mytnik and Gershon Wolansky.
    Lecture
  • Date:16ThursdayJanuary 2025

    Harnessing Cancer Paradigms for the Treatment of Heart Failure and Fibrosis

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    Time
    14:00 - 15:00
    Location
    Max and Lillian Candiotty Building
    LecturerProf. Ami Aronheim
    Department of Cell Biology and Cancer Science, Rappaport Faculty of Medicine, Technion.
    Organizer
    Moross Integrated Cancer Center (MICC)
    Contact
    Lecture
  • Date:16ThursdayJanuary 2025

    The ESCRT machinery: an evolutionary conserved, a multi-purpose membrane remodeling deviceounced

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    Time
    15:00 - 16:00
    Location
    Nella and Leon Benoziyo Building for Biological Sciences
    Auditorium room 191c
    LecturerProf. Natalie Elia
    The Department of Life Sciences, Ben-Gurion University
    Organizer
    Department of Biomolecular Sciences
    Contact
    AbstractShow full text abstract about <p>The ESCRT membrane remodeling complex, found across...»
    <p>The ESCRT membrane remodeling complex, found across all life forms, exhibits a versatility that transcends evolutionary boundaries. From orchestrating the constriction of micron-wide tubes in cell division to facilitating the budding of 50 nm vesicles in receptor degradation, ESCRTs perform diverse functions in animal cells. In recent years, ESCRT homologs were identified in prokaryotes, highlighting a role for this protein machinery in the ancient world.&nbsp;&nbsp;We seek to understand the mechanistic principles underlying the functional diversity of the ESCRT system across evolution.&nbsp;Specifically, we focus on understanding how the ESCRT complex orchestrate in cells to constrict and cut membranes in eukaryotes, focusing on its role in cell division, and in prokaryotes, focusing on the recently discovered Asgard archaea.&nbsp;By combining high-resolution imaging with biochemical and structural studies we aim to unlock the secrets of this fundamental membrane remodeling machinery and its potential role in evolution.</p>
    Lecture
  • Date:19SundayJanuary 2025

    Allochthonous groundwater microorganisms affect coastal seawater microbial abundance, activity and diversity

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    Time
    11:00 - 12:00
    Location
    Sussman building
    M. Magaritz seminar room
    AbstractShow full text abstract about <p>Submarine groundwater discharge (SGD) is a globally...»
    <p>Submarine groundwater discharge (SGD) is a globally important process</p><p>supplying nutrients and trace elements to the coastal environment, thus</p><p>playing a pivotal role in sustaining marine primary productivity. Along with</p><p>nutrients, groundwater also contains allochthonous microbes that are</p><p>discharged from the terrestrial subsurface into the sea. Currently, little is</p><p>known about the interactions between groundwater-borne and coastal</p><p>seawater microbial populations, and groundwater microbes' role upon</p><p>introduction to coastal seawater populations. In the current study we</p><p>investigated seawater microbial abundance, activity and diversity in a site</p><p>strongly influenced by SGD. In addition, through laboratory-controlled</p><p>bottle incubations, we mimicked different mixing scenarios between</p><p>groundwater and seawater. Our results demonstrate that the addition of</p><p>0.1 μm filtered groundwater stimulated heterotrophic activity and</p><p>increased microbial abundance compared to control coastal seawater,</p><p>whereas 0.22 μm filtration treatments induced primary productivity and</p><p>Synechococcus growth. 16S rRNA gene sequencing showed a strong</p><p>shift from a SAR11-rich community in the control samples to</p><p>Rhodobacteraceae dominance in the &lt;0.1 μm treatment, in agreement</p><p>with Rhodobacteraceae enrichment in the SGD field site. These results</p><p>suggest that microbes delivered by SGD may affect the abundance,</p><p>activity and diversity of intrinsic microbes in coastal seawater, highlighting</p><p>the cryptic interplay between groundwater and seawater microbes in</p><p>coastal environments, which has important implications for carbon</p><p>cycling.</p>
    Lecture
  • Date:19SundayJanuary 2025

    The Clore Center for Biological Physics

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    Time
    12:45 - 14:30
    Title
    A social view of viral decision making
    Location
    Nella and Leon Benoziyo Physics Library
    LecturerProf. Avigdor Eldar
    lunch will be served at 12:45
    Organizer
    Clore Center for Biological Physics
    Contact
    AbstractShow full text abstract about <p><br>Temperate bacterial viruses (or phages) h...»
    <p><br>Temperate bacterial viruses (or phages) have two divergent life cycles when infecting their host; A virulent (lytic) cycle where they rapidly replicate to produce hundreds of virions and kill their host, or a dormant (lysogenic) cycle where it typically integrates into the host genome and replicate with it. The social environment of the cell is a major determinant of the phage’s decision between its life cycles, but the consequences of sociality are still being explored. In this lecture, I will introduce the canonical phage lambda model where this has been studied and a recent model for phage sociality which is based on detection of small molecule signals. I will then discuss three works which combine experiments, genomics and theory to discuss the nature of social signals in different systems and their implication for phage decision making, social cooperation and their evolution.</p><p>&nbsp;</p><p><strong>FOR THE LATEST UPDATES AND CONTENT ON SOFT MATTER AND BIOLOGICAL PHYSICS AT THE WEIZMANN, VISIT OUR&nbsp;WEBSITE:&nbsp;https://www.biosoftweizmann.com/</strong></p><p>&nbsp;</p>
    Lecture
  • Date:22WednesdayJanuary 2025

    "Though the city used to be called Luz" –SIRT6, aging and beyond.

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    Time
    11:00 - 12:00
    Title
    The mammalian longevity associated acetylome
    Location
    Arthur and Rochelle Belfer Building for Biomedical Research
    LecturerDr. Haim Cohen
    Organizer
    Sagol Institute for Longevity Research
    Contact
    AbstractShow full text abstract about <p>Despite extensive studies at the genomic, transcrip...»
    <p>Despite extensive studies at the genomic, transcriptomic, and metabolomic levels, the underlying mechanisms regulating longevity remain incompletely understood. Post-translational protein acetylation has been suggested to regulate aspects of longevity. To further explore the role of acetylation, we developed the PHARAOH computational tool, based on the 100-fold differences in longevity within the mammalian class. Analyzing acetylome and proteome data across 107 mammalian species identified multiple significant longevity-associated acetylated lysine residues in mice and humans, controlling many longevity-related pathways. Specifically, we found that longevity-associated acetylation sites help resolve the Peto Paradox: the enigma of why animals with increased body size live longer yet do not exhibit much higher cancer incidence. Our findings show a significant positive correlation between these new acetylation sites and protection against multiple types of cancer in humans. Moreover, mutating these sites reduced the anti-neoplastic functions of the acetylated proteins. These findings provide new insights into the pivotal role of protein acetylation in mammalian longevity, suggesting potential interventions to extend human healthspan.</p>
    Lecture
  • Date:22WednesdayJanuary 2025

    Deciphering the role of the DCC/UNC-40 receptor in dopaminergic neurons during health and disease

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    Time
    11:00 - 13:00
    Location
    Koshland Room, Belfer building
    LecturerSapir Sela
    student PhD defense seminar
    Organizer
    Department of Brain Sciences
    Contact
    AbstractShow full text abstract about <p>TheUNC-40 receptor, a homolog of the human DCC rece...»
    <p>TheUNC-40 receptor, a homolog of the human DCC receptor, is critical for neuronal development and maintenance, with its dysregulation implicated in neurodegenerative diseases such as Parkinson’s disease. This study investigates the role of UNC-40 in dopaminergic neuron health and degeneration using Caenorhabditis elegans as a model system. Loss-of-function mutations in UNC-40 conferred resistance to 6-hydroxydopamine (6-OHDA)-induced DA neuron degeneration, while stabilization of UNC-40 via mutation in the CPD regulatory site led to spontaneous, selective DA neurodegeneration independent of toxins. Mechanistic analyses revealed that UNC-40 stabilization triggers parthanatos, a caspase-independent cell death pathway driven by mitochondrial oxidative stress. Pharmacological inhibition of PARP-1 and treatment with mitochondrial antioxidants significantly rescued DA neurons from degeneration.suggesting UNC-40 stabilization causes mitochondrial oxidative stress. Remarkably, UNC-40-induced degeneration was sexually dimorphic, affecting hermaphrodites but not males. Transcriptomic analyses revealed significant gene expression changes in hermaphrodites carrying stabilized UNC40, while males exhibited minimal changes, suggesting intrinsic protective mechanisms. UNC-6, a ligand for UNC-40, was identified as a critical external factor modulating this dimorphism; its absence in hermaphrodites rendered them vulnerable, while its presence in males made them unaffected by the stabilization of the receptor. Behavioral assays revealed functional impairments in hermaphrodites with stabilized UNC-40, linked to altered synaptic activity and excitotoxicity. These findings establish UNC-40 as a key regulator of DA neuron health, highlight its role in oxidative stress and synaptic maintenance, and underscore sexually dimorphic vulnerability to neurodegeneration. The parallels between UNC-40 in C. elegans and DCC in humans suggest conserved mechanisms underlying neurodegeneration and point to potential therapeutic targets for diseases like PD.</p>
    Lecture
  • Date:22WednesdayJanuary 2025

    Machine Learning and Statistics Seminar

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    Time
    11:15 - 12:15
    Title
    Algorithmic Dependent Generalization Bounds: Some lower and upper bounds
    Location
    Jacob Ziskind Building
    Room 1 - 1 חדר
    LecturerRoi Livni
    Tel-Aviv University
    Organizer
    Department of Computer Science and Applied Mathematics
    Contact
    AbstractShow full text abstract about The role of the algorithm in generalization remains one of t...»
    The role of the algorithm in generalization remains one of the least understood aspects of modern machine learning. Classical theories, such as VC-theory and PAC learning, posits that the sample size needed to fit a model depends only on the class to be learnt but not on the fitting algorithm itself. Yet, in practice, the algorithm plays a crucial role in avoiding overfitting. A well-studied framework to explore this possibility is Stochastic Convex Optimization, where the algorithm's influence on generalization is well established. We will discuss two recent results that try to shed light on how algorithms affect generalization.

    The first result examines the sample complexity of Gradient Descent. Arguably this is one of the simplest algorithms for this setup. We will present the first tight sample complexity bounds. These bounds demonstrate how, when applied naively, Gradient Descent performs no better than a worst-case empirical risk minimizer. However, with correct parameter tuning, the algorithm achieves optimal sample complexity rates, but in a computationally inefficient manner.

    The second result investigates the interplay between memorization and learning and the potential of information-theoretic generalization bounds. Contrary to the conventional view that successful learning avoids memorization, we will see that even in simple scenarios, memorization can be essential. This finding suggests that large-scale learning might, unintuitively, require complete memorization of the dataset.
    Lecture
  • Date:22WednesdayJanuary 2025

    The Tiny Tip’s Tremendous Touch

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    Time
    12:30 - 14:00
    Location
    Gerhard M.J. Schmidt Lecture Hall
    LecturerDr. Irit Rosenhek-Goldian
    Spotlight on Science lecture sponsored by the Staff Scientists Council
    Contact
    AbstractShow full text abstract about <p>The Scanning Probe Microscopy (SPM) Unit conducts a...»
    <p>The Scanning Probe Microscopy (SPM) Unit conducts a diverse range of scientific projects, spanning from the life sciences (<em>e.g.</em>, vesicles, cells, and shells) to material science (<em>e.g.</em>, crystals and nanoparticles). Beyond 3D topographic imaging, scanning probe microscopy provides a comprehensive understanding of a material by measuring mechanical, electrical, and other properties. Recent advancements in our unit, including correlative AFM-SEM systems and rapid scanning capabilities, expand the AFM's potential for studying dynamic processes and for more efficient data acquisition. Moreover, machine learning methods have been harnessed to improve analysis accuracy.</p><p></p><p>In this talk, I will present the technique and bring examples where AFM has provided critical insight into various scientific fields by illuminating the nanoscale.</p>
    Lecture
  • Date:22WednesdayJanuary 2025

    ABC CHATS- Alon Levy- Seri from Sol-Gel

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    Time
    14:00 - 15:30
    Title
    From Academic Research to FDA Approved Innovative Drugs
    Location
    George and Esther Sagan Students' Residence Hall
    Lounge
    LecturerAlon Seri-Levy - co-founder of Sol-Gel
    Alon will take you on a short journey summarizing his 3 decades of experience at Sol-Gel (NASDAQ: SLGL) which licensed in technology from The Hebrew University and developed it all the way to innovative drugs on the US market.  He will give examples of good decisions he made and mainly of his wrong decisions.
    Contact
    AbstractShow full text abstract about <p>Join our ABC CHATS where CEO's share their ABC...»
    <p>Join our ABC CHATS where CEO's share their ABC's</p><p>on scientific leadership, breakthroughs and failures throughout their personal stories </p>
    Cultural Events
  • Date:23ThursdayJanuary 2025

    Physics Colloquium

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    Time
    11:15 - 12:30
    Title
    It takes two to tango: The physics of heterogeneous bacterial active matter systems
    Location
    Physics Weissman Auditorium
    LecturerProf. Joel Stavans
    Light refreshments at 11:00
    Organizer
    Department of Physics of Complex Systems
    Contact
    AbstractShow full text abstract about <p>Non-equilibrium active matter systems often exhibit...»
    <p>Non-equilibrium active matter systems often exhibit self-organized, collective motion that can give rise to the emergence of coherent spatial structures. Prime examples covering many length scales range from mammal herds, fish schools and bird flocks, to insect and robot swarms. Despite significant advances in understanding the behavior of homogeneous systems in the last decades, little is known about the self-organization and dynamics of heterogeneous active matter. I will present results of bioconvection experiments with multispecies suspensions of wild-type bacteria from the hyper-diverse bacterial communities of Cuatro Ciénegas, Coahuila, whose origin dates back to the pre-Cambrian. Under oxygen gradients, these bacteria swim in auto-organized, directional flows, whose spatial scales exceed the cell size by orders of magnitude, demonstrating a plethora of amazing dynamical behaviors, including segregation. I will present evidence supporting the notion that the mechanisms giving rise to these complex behaviors are predominantly physical, and not a result of biological interactions. This research significantly advances our understanding of both heterogeneity in active matter, as well as in the dynamics of complex microbial ecological communities, bringing profound insights into their spatial organization and collective behavior.</p>
    Colloquia
  • Date:23ThursdayJanuary 2025

    Vision and AI

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    Time
    12:15 - 13:15
    Title
    Trainable Highly-expressive Activation Functions
    Location
    Jacob Ziskind Building
    Room 1 - 1 חדר
    LecturerIrit Chelly & Shira Ifergane
    BGU
    Organizer
    Department of Computer Science and Applied Mathematics
    Contact
    AbstractShow full text abstract about Nonlinear activation functions are pivotal to the success of...»
    Nonlinear activation functions are pivotal to the success of deep neural nets, and choosing the appropriate activation function can significantly affect their performance. Most networks use fixed activation functions (e.g., ReLU, GELU, etc.), and this choice might limit their expressiveness. Furthermore, different layers may benefit from diverse activation functions. Consequently, there has been a growing interest in trainable activation functions. In this paper, we introduce DiTAC, a trainable highly-expressive activation function based on an efficient diffeomorphic transformation (called CPAB). Despite introducing only a negligible number of trainable parameters, DiTAC enhances model expressiveness and performance, often yielding substantial improvements. It also outperforms existing activation functions (regardless whether the latter are fixed or trainable) in tasks such as semantic segmentation, image generation, regression problems, and image classification. The talk is based on [Chelly et. all, ECCV '24].

    Paper:

    https://arxiv.org/abs/2407.07564

    Speakers' short bio:

    Irit Chelly is a PhD student in the Computer Science department at Ben-Gurion University, where she also earned her M.Sc., under the supervision of Dr. Oren Freifeld in the Vision, Inference, and Learning group. Her research focuses on probabilistic clustering using non-parametric Bayesian models and unsupervised learning. Her previous projects involved spatial transformations and dimensionality reduction in video analysis, and generative models. Irit won the national-level Aloni PhD scholarship from Israel's Ministry of Technology and Science as well as the BGU Hi-tech scholarship for excellent PhD students, and received annually awards and instructor rank for outstanding teaching skills in essential courses in the Computer Science department. 

    Shira Ifergane is an MSc Computer Science student at BGU, working at the Vision, Inference, and Learning group under the supervision of Prof. Oren Freifeld. Shira co-authored an ECCV 2024 paper and has won the national MS scholarship for AI and Data Science research from Israel's Council for Higher Education. Her current research centers on efficient deep models for video analysis.
    Lecture
  • Date:23ThursdayJanuary 2025

    Geometric Functional Analysis and Probability Seminar

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    Time
    13:30 - 15:00
    Title
    Affirmative Resolution of Bourgain's Slicing Problem using Guan's Bound
    Location
    Jacob Ziskind Building
    Room 155 - חדר 155
    LecturerBo'az Klartag
    Weizmann Institute of Science
    Organizer
    Department of Mathematics
    Contact
    AbstractShow full text abstract about We provide the final step in the resolution of Bourgain'...»
    We provide the final step in the resolution of Bourgain's slicing problem in the affirmative. Thus we establish the following theorem: for any convex body K in R^n of volume one, there exists a hyperplane H, such that the (n-1)-dimensional volume of the intersection of K with H is at least c. Here c > 0 is a universal constant. Our proof combines Milman's theory of M-ellipsoids, stochastic localization with a recent bound by Guan, and stability estimates for the Shannon-Stam inequality by Eldan and Mikulincer.

    Joint work with J. Lehec.
    Lecture
  • Date:27MondayJanuary 2025

    Integrating Peptides and DNA for Tailored Material Design

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    Time
    11:00 - 12:00
    Location
    Schmidt Lecture Hall
    LecturerDr. Zohar A. Arnon
    Organizer
    Department of Molecular Chemistry and Materials Science
    Contact
    AbstractShow full text abstract about <p>In nature, sequence-specific biopolymers, such as p...»
    <p>In nature, sequence-specific biopolymers, such as peptides and nucleic acids, are essential to various biological systems and processes. These biopolymers are utilized in materials science to achieve precise property control. Typically, variations in amino acid sequences focus on functional regulation while nucleotides are used for structural control. This raises the question: How can we integrate peptide-based functionality with the spatial precision of DNA nanotechnology for innovative material design? Here, I will present examples illustrating the incredible properties of peptide self-assembly from my PhD, and the remarkable nanoarchitecture design achieved through DNA nanotechnology from my Postdoc. These two key elements establish a vision of utilizing and synergizing peptide functionality with structural control achieved by DNA nanotechnology.</p><p>Specifically, I will show how subtle changes in the molecular environment influence the morphology and behavior of peptide assemblies such as diphenylalanine crystals and enable control over their growth and disassembly processes, revealing insights into peptide-based material manipulation (Nat. Commun., 2016). Another example is that of the amorphous assemblies of tri-tyrosine peptides, where we linked the molecular arrangement to unique mechanical and optical properties of glass-like peptide structures (Nature, 2024).</p><p>Next, I will introduce the principles of DNA nanotechnology for advanced structural control. By designing DNA nano-frames capable of self-assembling into organized lattices, we created micron-scale 3D materials. We discovered that a minor modification in DNA linker length induces a crystalline phase transition, from simple cubic to face-centered cubic structures, altering lattice geometry. In addition, we established a method using acoustic waves to achieve scalable and morphologically controllable DNA assemblies at the millimetric scale (Nat. Commun., 2024). This approach highlights how DNA nanotechnology provides unparalleled spatial control, decoupling structural architecture from functional elements such as peptides and nanoparticles. Together, these projects illustrate how peptides and DNA nanotechnology can be potentially integrated to engineer novel materials and enhance our capacity to design materials with tailored properties across scales.</p>
    Lecture
  • Date:27MondayJanuary 2025

    Physics Colloquium

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    Time
    11:15 - 12:30
    Title
    Programmable quantum many-body physics with Rydberg atom arrays
    Location
    Nella and Leon Benoziyo Physics Library
    LecturerDr. Tom Manovitz
    Light refreshments will be served at 11:00
    Organizer
    Department of Physics of Complex Systems
    Contact
    AbstractShow full text abstract about <p>Programmable quantum platforms have emerged as powe...»
    <p>Programmable quantum platforms have emerged as powerful tools for studying quantum many-body phenomena, with applications ranging from condensed matter and high energy physics to quantum algorithms. In this talk, I will discuss recent developments involving programmable Rydberg atom arrays, which allow for precise and coherent control of hundreds of atoms in two dimensions, along with individual addressability and reconfigurable geometry. First, I will describe explorations of ordering dynamics in a quantum magnet following a quantum phase transition. Using individual atom control, we uncover the interplay of quantum criticality and non-equilibrium phenomena, and observe long-lived oscillations of the order parameter akin to an amplitude (“Higgs”) mode, with interesting implications near the quantum critical point. I will then describe the digital realization of the Kitaev honeycomb model, including observation of an exotic non-Abelian spin-liquid, as well as the use of topological order to design a programmable fermionic simulator. These measurements introduce new avenues for the study of quantum criticality and fermionic models, respectively. Finally, I will briefly discuss future opportunities in explorations of quantum many-body physics with atom arrays, with emphasis on new frontiers in the study of quantum criticality.</p>
    Colloquia
  • Date:28TuesdayJanuary 2025

    From Microbes to Human Brains: Unraveling and Targeting Amyloids via Advanced Structural Biology Tools

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    Time
    14:00 - 15:00
    Location
    Gerhard M.J. Schmidt Lecture Hall
    LecturerDr. Einav Tayeb-Fligelman
    Organizer
    Department of Chemical and Structural Biology
    Lecture
  • Date:29WednesdayJanuary 2025

    Special Guest Seminar

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    Time
    11:00 - 12:00
    Title
    Mapping Antibody-Mediated Mechanisms of Protection Against Shigella
    Location
    Max and Lillian Candiotty Building
    Auditorium
    LecturerDr. Biana Bernshtein
    Ragon Institute of MGH, MIT and Harvard
    Organizer
    Department of Immunology and Regenerative Biology
    Contact
    Lecture
  • Date:30ThursdayJanuary 2025

    In honor of the 100th birthday of Prof. Yigal Talmi

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    Time
    11:15 - 12:30
    Title
    Factorization and Universality in Nuclear Physics
    Location
    Physics Weissman Auditorium
    LecturerProf. Nir Barnea
    Organizer
    Faculty of Physics
    Contact
    AbstractShow full text abstract about <p>The study of dilute, strongly interacting quantum g...»
    <p>The study of dilute, strongly interacting quantum gases reveals</p><p>universal properties that transcend the specifics of individual</p><p>systems. These features arise from their short-range behavior</p><p>and are encapsulated in a key quantity called the “contact”, which</p><p>quantifies the probability of two particles being in close proximity.</p><p>In this talk, I will introduce the contact theory and its extension to</p><p>nuclear and molecular systems beyond the zero-range limit. I will</p><p>demonstrate its applicability in analyzing nuclear electron</p><p>scattering and photo absorption reactions.</p><p>Additionally, I will discuss how mean-field approximations, such as</p><p>the nuclear shell model, can effectively estimate the contact,</p><p>offering valuable insights into the underlying physics.</p>
    Colloquia
  • Date:30ThursdayJanuary 2025

    Vision and AI

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    Time
    12:15 - 13:15
    Title
    Understanding and Enhancing Deep Neural Networks with Automated Interpretability
    Location
    Jacob Ziskind Building
    Room 1 - 1 חדר
    LecturerTamar Rott Shaham
    MIT
    Organizer
    Department of Computer Science and Applied Mathematics
    Contact
    AbstractShow full text abstract about Deep neural networks are becoming incredibly sophisticated; ...»
    Deep neural networks are becoming incredibly sophisticated; they can generate realistic images, engage in complex dialogues, analyze intricate data, and execute tasks that appear almost human-like. But how do such models achieve these abilities?

    In this talk, I will present a line of work that aims to explain behaviors of deep neural networks. This includes a new approach for evaluating cross-domain knowledge encoded in generative models, tools for uncovering core mechanisms in large language models, and their behavior under fine-tuning. I will show how to automate and scale the scientific process of interpreting neural networks with the Automated Interpretability Agent, a system that autonomously designs experiments on models’ internal representations to explain their behaviors. I will demonstrate how such understanding enables mitigating biases and enhancing models’ performance. The talk will conclude with a discussion of future directions, including developing universal interpretability tools and extending interpretability methods to automate scientific discovery.

    Bio: 

    Tamar Rott Shaham is a postdoctoral researcher at MIT CSAIL in Prof. Antonio Torralba’s lab. She earned her PhD from the ECE faculty at the Technion, supervised by Prof. Tomer Michaeli. Tamar has received several awards, including the ICCV 2019 Best Paper Award (Marr Prize), the Google WTM Scholarship, the Adobe Research Fellowship, the Rothchild Postdoctoral Fellowship, the Vatat-Zuckerman Postdoctoral Scholarship, and the Schmidt Postdoctoral Award.
    Lecture

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