A human being is not attaining his full heights until he is educated
Colloquia
Physics Conference Room, SB B326
Coffee starts at 12:00 PM and talk starts at 12:15 PM
Coffee starts at 12:00 PM and talk starts at 12:15 PM
15
Feb '23
In-person
+ Online
+ Online
LPMMC University Grenoble Alpes/CNRS
Bart van Tiggelen
The subtle role of longitudinal waves in light scattering
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SB B326
Abstract:
Longitudinal electric fields exist in the presence of electric charges, either real or induced. They often hide in the near-field of an object, give rise to local-field factors, stock energy, but alone do not induce a Poynting vector.
I will discuss two cases where their role is far from innocent. In a classical transport theory for electromagnatic waves inside media with electric dipoles, longitudinal waves mix with transverse waves and induce a novel transport channel. This imposes a "minimum electromagnetic conductivity" and rules out Anderson localization. In QED, longitudinal electric fields are strongly connected to the vector potential. In the presence of an external magnetic field, the presence of longitudinal fields inside a medium with give rise to a diamagnetic Einstein - De Haas effect induced by the quantum vacuum.
I will discuss two cases where their role is far from innocent. In a classical transport theory for electromagnatic waves inside media with electric dipoles, longitudinal waves mix with transverse waves and induce a novel transport channel. This imposes a "minimum electromagnetic conductivity" and rules out Anderson localization. In QED, longitudinal electric fields are strongly connected to the vector potential. In the presence of an external magnetic field, the presence of longitudinal fields inside a medium with give rise to a diamagnetic Einstein - De Haas effect induced by the quantum vacuum.
22
Feb '23
In-person
+ Online
+ Online
Yale University
Sibel Yalcin
How do bacteria use quantum effects to respire without oxygen? Protein nanowires as spin polarizers with ultrafast electron transport
Abstract:
Cells compute with chemistry and semiconductors compute with transistors – but both operate by controlling the flow of electrons. Biochemistry typically allows electron flow in proteins only over a few nanometers, whereas semiconductors use wires that can conduct quickly over long distances. What if cells have designed biomolecules that behave like wires? To breathe, living cells typically use soluble, membrane-ingestible molecules, like oxygen, to dispose of electrons generated during metabolism. But, we have found that to “breathe” in deep ocean and underground anoxic environments, soil bacteria, Geobacter have evolved nanowires to export electrons to extracellular acceptors that could be hundreds of cell lengths away.
I will present our recent discoveries that solve a longstanding mystery of how nanowires move electrons to soil minerals or help generate electricity. By correlating cryo-electron microscopy with multimodal functional imaging and a suite of electrical, biochemical and physiological studies, we find that nanowires are made up of polymerized cytochrome proteins that transport electrons via seamless stacking of metal-containing heme molecules over micrometer distances (Cell 2019, Nature Chem.Bio. 2020, Nature 2021). As metalloproteins were not known to polymerize, the discovery of these cytochrome nanowires opens an entirely new field for the development of next-generation living bioelectronics. My recent experimental studies on individual nanowires show inherent spin polarization and the highest electronic conductivity reported on proteins (> 100 S/cm with ultrafast electron transfer rate of ~200 fs). Computational studies suggest that quantum coherent transport accounts for the high conductivity of these nanowires. Identifying the role of quantum effects in these processes will help understand, predict, and ultimately control extracellular electron transfer by protein nanowires used by diverse environmentally important microbes to capture, convert and store energy. Moreover, cytochrome nanowires acting as Biocompatible Quantum Probes at room temperature will enable a route to engineer quantum technologies based on biology.
I will present our recent discoveries that solve a longstanding mystery of how nanowires move electrons to soil minerals or help generate electricity. By correlating cryo-electron microscopy with multimodal functional imaging and a suite of electrical, biochemical and physiological studies, we find that nanowires are made up of polymerized cytochrome proteins that transport electrons via seamless stacking of metal-containing heme molecules over micrometer distances (Cell 2019, Nature Chem.Bio. 2020, Nature 2021). As metalloproteins were not known to polymerize, the discovery of these cytochrome nanowires opens an entirely new field for the development of next-generation living bioelectronics. My recent experimental studies on individual nanowires show inherent spin polarization and the highest electronic conductivity reported on proteins (> 100 S/cm with ultrafast electron transfer rate of ~200 fs). Computational studies suggest that quantum coherent transport accounts for the high conductivity of these nanowires. Identifying the role of quantum effects in these processes will help understand, predict, and ultimately control extracellular electron transfer by protein nanowires used by diverse environmentally important microbes to capture, convert and store energy. Moreover, cytochrome nanowires acting as Biocompatible Quantum Probes at room temperature will enable a route to engineer quantum technologies based on biology.
Notes:
Room C203
27
Feb '23
In-person
+ Online
+ Online
École polytechnique Fédérale de Lausanne
Jose Negrete
Gene expression dynamics at the single cell level and tissue patterning in embryo segmentation
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SB B326
Abstract:
In vertebrate embryos the sequential segmentation of the pre-somitic mesoderm (PSM) creates a tissue structure associated with the vertebral column. Before a given segment is created, the tissue is pre-patterned by the expression of different genes at different locations. Do cells create these patterns by expressing genes independently within cells, or do the patterns emerge by collective behaviour? In this talk I'll show that for zebrafish embryos, a significant part of the patterning process is encoded within single cells. More specifically, I'll show that a model of a cell containing a stochastic genetic timer and a stochastic genetic clock reproduce the observed gene expression dynamics observed in vivo and in vitro. Finally, this model is extended by introducing the entry rate of the cells to the PSM, and reproduces non-trivial features observed in the patterning of the embryo. This work extends our understanding on how cells pattern the PSM before creating a segment, and also introduces a new strategy for tissue patterning within embryos.
Notes:
Physics Conference Room, SB B326
3
Mar '23
In-person
+ Online
+ Online
Princeton University
Kelsey Hallinen
Population Dynamics in Complex Biological Systems
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SB B326
Abstract:
Employing tools from statistical physics and complex systems, my research focuses on understanding collective behavior in biological systems. Using a mix of experimental studies and physics driven modeling, I have been able to elucidate rules and equations that can explain the complex, collective behavior in a variety of systems, from bacterial populations to neural networks. In this talk, I will discuss my previous research examining the dynamics in a mixed population of antibiotic resistant and sensitive bacterial cells as well as population decoding studies of neural signals in the small nematode C. elegans. Through these examples, I will demonstrate how my collective systems approaches can generate insights into how groups of simple actors- such as bacterial cells or neurons- can lead to complex emergent outcomes. As I look towards my future work, I will apply these collective systems approach towards another complex system, bacteria in flow. I will discuss my preliminary results and future plans for studying bacterial adherence and dynamics in complex flow environments, inspired by clinical endocarditis infections.
13
Mar '23
In-person
+ Online
+ Online
Harvard Medical School and Massachusetts General Hospital
Sithara Wijeratne
Self-Organization and Dynamics of Cellular Highways
Abstract:
Analogous to the role of highways in our macroscopic world, the cytoskeleton organizes the cellular cytoplasm. Micron-sized cytoskeletal polymers, such as microtubules, link distant cellular sites. Nanometer-sized motor proteins walk on complex multi-microtubule highway systems to drive intracellular transport and also remodel the "highway". I will present two different aspects of microtubule organization in my seminar. First, I present an unexpected discovery that nanometer-sized proteins separated by several microns on microtubules can sense and respond to each other. This challenges the long-held view of microtubules as a passive platform and reveals how the microtubule is like a wooden bridge rather than a concrete highway. Second, I present the development of an Atomic Force Microscopy assay that enables us to directly visualize the dynamic features of individual microtubules within complex microtubule arrays. This imaging modality bridges the resolution gap between light and electron microscopy to reveal new insights by which complex microtubule arrays can be remodeled by associated proteins.
15
Mar '23
In-person
+ Online
+ Online
University of California, San Diego
Wen Ma
Building a computational microscope to investigate the design principles and functions of biomolecular machines
Abstract:
The health of our body is manifested at the cellular level by interactions between biomolecular machines. A mechanistic understanding of cellular processes at the molecular level is crucial for designing effective strategies to combat various diseases. In this seminar, I will present my work on developing a “computational microscope” that combines physics, molecular simulations, and machine learning to investigate exemplary molecular motor systems that play key roles in genome maintenance and cardiac muscle contraction. Firstly, I have developed rare-event sampling techniques based on statistical physics to search for the most probable transition pathways for biomolecular processes. The methodology enables me to capture the millisecond dynamics of helicase motors translocating nucleic acid substrates. Secondly, by integrating informatics approaches with molecular simulations, I was able to reveal how the myosin-actin complex generates force in the human heart muscle, providing insights into the allosteric network encoded in the machine. The computational platform directly links the protein sequence space to their functions. Finally, I will discuss my plans to study the emergent behaviors of the actin-myosin systems, engineer molecular motors with novel functions, and develop strategies for treating cardiomyopathy.
20
Mar '23
In-person
+ Online
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CUNY Advanced Science Research Center
Qiushi Guo
Lithium niobate integrated nonlinear photonics: new devices and systems on an old material
Abstract:
Despite being an old material in optical and microwave technologies in its bulk form, thin-film lithium niobate (TFLN) has recently emerged as one of the most promising integrated photonic platforms owing to its strong electro-optic (EO) coefficient, quadratic optical nonlinearity, and broadband optical transparency ranging from 250 nm to 5 µm. In this talk, I will first overview the basic optical properties of LN, and how LN nanophotonics can grant us new regimes of nonlinear light-matter interactions. Then I will present some of our recent experimental results on the realization and utilization of dispersion-engineered and quasi-phase-matched ultrafast photonic devices in both classical and quantum domains. I will discuss the realization of 100 dB/cm optical parametric amplification [1], 1.5-3 µm widely tunable optical parametric oscillator (OPO) [2], ultra-wide bandwidth quantum squeezing [3], femtosecond and femtojoule on chip all-optical switching [4], and the integrated mode-locked lasers based on TFLN [5].
[1] L. Ledezma*, R. Sekine*, Q. Guo*, R. Nehra, S. Jahani, and A. Marandi, "Intense optical parametric amplification in dispersion-engineered nanophotonic lithium niobate waveguides," Optica, vol. 9, pp. 303-308, 2022.
[2] L. Ledezma, A. Roy, L. Costa, R. Sekine, R. Gray, Q. Guo, et al., "Widely-tunable optical parametric oscillator in lithium niobate nanophotonics," arXiv preprint arXiv:2203.11482, 2022.
[3] R. Nehra*, R. Sekine*, L. Ledezma, Q. Guo, R. M. Gray, A. Roy, et al., "Few-cycle vacuum squeezing in nanophotonics," Science, 2022.
[4] Q. Guo*, R. Sekine*, L. Ledezma*, R. Nehra, D. J. Dean, A. Roy, et al., "Femtojoule femtosecond all-optical switching in lithium niobate nanophotonics," Nature Photonics, vol. 16, pp. 625-631, 2022.
[5] Q. Guo et. al. Actively mode-locked laser in nanophotonic lithium niobate with Watt-level peak power (To be submitted).
[1] L. Ledezma*, R. Sekine*, Q. Guo*, R. Nehra, S. Jahani, and A. Marandi, "Intense optical parametric amplification in dispersion-engineered nanophotonic lithium niobate waveguides," Optica, vol. 9, pp. 303-308, 2022.
[2] L. Ledezma, A. Roy, L. Costa, R. Sekine, R. Gray, Q. Guo, et al., "Widely-tunable optical parametric oscillator in lithium niobate nanophotonics," arXiv preprint arXiv:2203.11482, 2022.
[3] R. Nehra*, R. Sekine*, L. Ledezma, Q. Guo, R. M. Gray, A. Roy, et al., "Few-cycle vacuum squeezing in nanophotonics," Science, 2022.
[4] Q. Guo*, R. Sekine*, L. Ledezma*, R. Nehra, D. J. Dean, A. Roy, et al., "Femtojoule femtosecond all-optical switching in lithium niobate nanophotonics," Nature Photonics, vol. 16, pp. 625-631, 2022.
[5] Q. Guo et. al. Actively mode-locked laser in nanophotonic lithium niobate with Watt-level peak power (To be submitted).
27
Mar '23
In-person
+ Online
+ Online
Nuclear Physics Institute of the Czech Academy of Sciences and Queens College
Kevin Zelaya
Lieb lattices and pseudospin-1 dynamics under barrier- and well-like electrostatic interactions
Abstract:
In this talk, I'll discuss the confining and scattering phenomena of electrons in a Lieb lattice subjected to the influence of a rectangular electrostatic barrier. In this setup, hopping amplitudes between nearest neighbors in orthogonal directions are considered different, and the next-nearest neighbor interaction describes spin-orbit coupling. This makes it possible to confine electrons and generate bound states, the exact number of which is exactly determined for null parallel momentum to the barrier. In such a case, it is proved that one even and one odd bound state is always generated, and the number of bound states increases for non-null and increasing values of the parallel momentum. That is, these bound states carry current. In the scattering regime, the exact values of energy are determined where the resonant tunneling occurs. The existence of perfect tunneling energy in the form of super-Klein tunneling is proved to exist regardless of the bang gap opening. Finally, it is shown that perfect reflection appears when solutions are coupled to the intermediate flat-band solution.
3
Apr '23
In-person
+ Online
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Yale University
Ian Moult
Imaging the Intrinsic and Emergent Scales of Quantum Chromodynamics with Colliders
Abstract:
The most powerful means of understanding nature at the smallest length scales is through the use of particle colliders. Colliders smash particles together at high energies, briefly producing new particles through quantum fluctuations, which then decay into complicated sprays of energy in surrounding detectors. Much in analogy with how the details of our cosmic history are imprinted in the cosmic microwave background, the detailed features of the interactions of elementary particles are imprinted into macroscopic correlations in the energy flow of the collision products. Understanding the underlying microscopic physics in collider experiments therefore relies on our ability to decode these complicated correlations in energy flow. In turn, the desire to understand how to compute collider observables from an underlying quantum field theory (QFT) description has been a driver of theoretical developments and insights into the structure of QFT.
17
Apr '23
In-person
+ Online
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Villanova University
Rebecca Phillipson
The Topology of Chaos: A Nonlinear Perspective on Accreting Compact Objects
Abstract:
Accreting compact objects such as neutron stars and black holes in X-ray Binaries (XRBs) and the supermassive black holes at the center of galaxies, called Active Galactic Nuclei (AGN), exhibit complex variability in their emission. The variability is ubiquitous and operates over a wide range of timescales from seconds up to years. Traditional studies of XRBs and AGN in large time domain surveys aim to connect stochastic characterizations of the variability to the underlying physical processes responsible for accretion onto the compact object, but frequently fail to capture nonlinear or higher-order modes of variability. Methods from topology and nonlinear dynamics distinguish between deterministic, chaotic, and stochastic behavior, and can be used to identify modes of variability that relate to dominant accretion processes. I will review several applications of nonlinear dynamics and chaos theory to the study of both XRBs and AGN that show a connection between nonlinear behavior and the underlying accretion processes. I will outline an approach from nonlinear time series analysis – called recurrence analysis – applied to the systematic and ensemble study of variable sources that can inform current and future time domain missions.
1
May '23
In-person
+ Online
+ Online
Tata Institute of Fundamental Research and Queens College
Krishna Joshi
Lasing over Anderson localized transport in 1D non-Hermitian photonic structures
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Science Building B326
Abstract:
By deliberately introducing disorder into the lattices, we manipulate propagation to produc e conductive or localized transport. The role of dimensionality, in particular, is important in such phenomena. In this talk, I will present the statistical properties of photons transport in 1D quasi-periodic amplifying structures with inherent non-Hermiticity. Specifically, I will talk about the lasing in Anderson localized states near a critical degree of disorder. Because of the presence of non-Hermiticity and amplification, we can investigate gain/loss phenomena as well as coupling between Anderson localized modes.
5
May '23
In-person
+ Online
+ Online
California Polytechnic State University
Oleg Kogan
Tunable intracellular transport on converging microtubule morphologies
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@12:35 pm
Abstract:
Cargo inside cells is transported by molecular motors that move ballistically on cytoskeleton, interspersed with diffusive episodes when motor-cargo complexes detach from the cytoskeleton. A common type of cytoskeletal morphology involves multiple converging microbutubules with their minus ends collected at the microtubule organizing center (MTOC) in the interior of the cell. This arrangement enables MTOC to serve as a trap, enabling agglomeration of cargo. The general principles governing dynamics, efficiency, and tunability of transport and trapping ability of MTOC is not fully understood. To address this, we develop a one-dimensional model that includes advective transport towards an attractor (such as the MTOC), and diffusive transport that allows particles to reach absorbing boundaries (such as cellular membranes). We show that the mean first passage time (MFPT) to reach the boundaries experiences a dramatic growth in magnitude, transitioning from a low to high MFPT regime over a window of cargo attachment-detachment rates that is close to in vivo values. Furthermore, we find that increasing either the attachment or detachment rate can result in optimal dispersal away from MTOC when the attractor is placed asymmetrically. Finally, we also describe a regime of rare events where the MFPT scales exponentially with advective velocity towards the attractor and the escape location becomes exponentially sensitive to the attractor positioning. Taken together, our results suggest that structures such as the MTOC allow for the sensitive control of the spatial and temporal features of transport and corresponding function under physiological conditions.
22
May '23
In-person
+ Online
+ Online
Stony Brook University
Mengkun Liu
Imaging Landau Quantized Polaritons Through Nano-light
Abstract:
Subwavelength confinement, chiral sensing, and frequency conversion of light at the nanoscale are highly desirable for future photonic and optoelectronic applications of quantum materials. By breaking the time-reversal symmetry, magnetic field enables novel light-matter interactions with important real-space features such as chiral magnetopolaritons, unidirectional edge photocurrent, and nonreciprocal light propagation at magnetic interfaces. However, due to many technical difficulties, these important magneto-optical phenomena and their applications at the nanoscale have not been investigated in real space at infrared (IR) or terahertz (THz) frequencies. In this talk, I report a direct visualization of the infrared magnetoexciton polaritons due to quantized Landau transitions in near-charge neutral graphene, using a novel magneto scanning near-field optical microscope (m-SNOM) working in a magnetic field up to 7 Tesla. We map the magnetic field-dependent polariton excitation and propagating at the edge of graphene and hBN and explore its associated enhanced chiral edge photocurrent down to the quantum Hall region. Our approach establishes m-SNOM as a versatile platform for exploring magneto-optical effects at the nanoscale. This preliminary research sets the stage for future spectroscopic investigations of the topological and chiral photonic phenomena in complex quantum materials using low-energy photons.
Mengkun Liu (Ph.D. 2012 Boston University) is an associate professor at the Department of Physics and Astronomy of Stony Brook University (since Jan. 2015). His post doc research was at UC San Diego from 2012-2014. His research interests include physics of correlated electron systems, low-dimensional quantum materials, infrared and terahertz nano-optics and ultrafast time-domain spectroscopy. Prizes include NSF career award (2021) and Seaborg Institute Research Fellowships at Los Alamos National Lab (2009, 2010).
Mengkun Liu (Ph.D. 2012 Boston University) is an associate professor at the Department of Physics and Astronomy of Stony Brook University (since Jan. 2015). His post doc research was at UC San Diego from 2012-2014. His research interests include physics of correlated electron systems, low-dimensional quantum materials, infrared and terahertz nano-optics and ultrafast time-domain spectroscopy. Prizes include NSF career award (2021) and Seaborg Institute Research Fellowships at Los Alamos National Lab (2009, 2010).
8
Jun '23
In-person
+ Online
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Sandia National Laboratories
Igal Brener
Nonlinear and Quantum Semiconductor Metasurfaces
Abstract:
Metamaterials and their 2D implementation – metasurfaces - have been used extensively for wavefront manipulation since their inception nearly two decades ago. This has led to a revolution in optics due to the ability to design opticalcomponents with functionality and form factor that was unthinkable not long ago. Another use of metasurfaces relies on the ability to tailor distributions and intensities of local electromagnetic fields to study a variety of fundamental phenomena in light-matter interaction, create novel tunable and active devices and enhance optical nonlinearities.
In the context of quantum and nonlinear optics, III-V semiconductors have among the highest optical nonlinearities but cannot be used in conventional phase-matched processes due to the symmetry of their nonlinear susceptibility tensor. However, as phase matching is relaxed when resonant nanoscale resonators are used, III-V semiconductor metasurfaces can be used for harmonic generation, harmonic mixing and parametric down-conversion in ways thathave no equivalence when using macroscopic nonlinear media. Some of the results that I’ll present include harmonicgeneration and generation of entangled photons and complex quantum states using spontaneous parametric downconversion enabled by quasi bound-states in the continuum resonances. If time permits, I will also show recentresults of beam steering of spontaneous emission from semiconductor metasurfaces.
In the context of quantum and nonlinear optics, III-V semiconductors have among the highest optical nonlinearities but cannot be used in conventional phase-matched processes due to the symmetry of their nonlinear susceptibility tensor. However, as phase matching is relaxed when resonant nanoscale resonators are used, III-V semiconductor metasurfaces can be used for harmonic generation, harmonic mixing and parametric down-conversion in ways thathave no equivalence when using macroscopic nonlinear media. Some of the results that I’ll present include harmonicgeneration and generation of entangled photons and complex quantum states using spontaneous parametric downconversion enabled by quasi bound-states in the continuum resonances. If time permits, I will also show recentresults of beam steering of spontaneous emission from semiconductor metasurfaces.
11
Sep '23
In-person
+ Online
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UCLA
Clarice Aiello
“Quantum Biology”: How nature harnesses quantum processes
Abstract:
“Quantum Biology”: how nature harnesses quantum processes to function optimally,
and how might we control such quantum processes to therapeutic and tech advantage
Imagine driving cell activities to treat injuries and disease simply by using tailored magnetic fields. Many relevant physiological processes, such as: the regulation of oxidative stress, proliferation, and respiration rates in cells; wound healing; ion channel functioning; and DNA repair were all demonstrated to be controlled by weak magnetic fields (with a strength on the order of that produced by your cell phone). Such macroscopic physiological responses to magnetic fields are consistent with being driven by chemical reactions that depend on the electron quantum property of spin. In the long-term, the electromagnetic fine-tuning of endogenous “quantum knobs” existing in nature could enable the development of drugs and therapeutic devices that could heal the human body — in a way that is non-invasive, remotely actuated, and easily accessible by anyone with a mobile phone. However, whereas spin-dependent chemical reactions have been unambiguously established for test-tube chemistry (bearing uncanny similarities with what physicists call “spin quantum sensing”), current research has not been able to deterministically link spin states to physiological outcomes in vivo and in real time. With novel quantum instrumentation, we are learning to control spin states within cells and tissues, having as a goal to write the “codebook” on how to deterministically alter physiology with weak magnetic fields to therapeutic and technological advantage.
Bio
Prof. Clarice D. Aiello is a quantum engineer interested in how quantum physics informs biology at the nanoscale. She is an expert on nanosensors harnessing room-temperature quantum effects in noisy environments. Aiello received her B.S. in Physics from the Ecole Polytechnique; her M.Phil. in Physics from the University of Cambridge, Trinity College; and her Ph.D. from MIT in Electrical Engineering. She also held postdoctoral appointments in Bioengineering at Stanford, and in Chemistry at Berkeley. Two months before the pandemic, she joined UCLA, where she leads the Quantum Biology Tech (QuBiT) Lab.
and how might we control such quantum processes to therapeutic and tech advantage
Imagine driving cell activities to treat injuries and disease simply by using tailored magnetic fields. Many relevant physiological processes, such as: the regulation of oxidative stress, proliferation, and respiration rates in cells; wound healing; ion channel functioning; and DNA repair were all demonstrated to be controlled by weak magnetic fields (with a strength on the order of that produced by your cell phone). Such macroscopic physiological responses to magnetic fields are consistent with being driven by chemical reactions that depend on the electron quantum property of spin. In the long-term, the electromagnetic fine-tuning of endogenous “quantum knobs” existing in nature could enable the development of drugs and therapeutic devices that could heal the human body — in a way that is non-invasive, remotely actuated, and easily accessible by anyone with a mobile phone. However, whereas spin-dependent chemical reactions have been unambiguously established for test-tube chemistry (bearing uncanny similarities with what physicists call “spin quantum sensing”), current research has not been able to deterministically link spin states to physiological outcomes in vivo and in real time. With novel quantum instrumentation, we are learning to control spin states within cells and tissues, having as a goal to write the “codebook” on how to deterministically alter physiology with weak magnetic fields to therapeutic and technological advantage.
Bio
Prof. Clarice D. Aiello is a quantum engineer interested in how quantum physics informs biology at the nanoscale. She is an expert on nanosensors harnessing room-temperature quantum effects in noisy environments. Aiello received her B.S. in Physics from the Ecole Polytechnique; her M.Phil. in Physics from the University of Cambridge, Trinity College; and her Ph.D. from MIT in Electrical Engineering. She also held postdoctoral appointments in Bioengineering at Stanford, and in Chemistry at Berkeley. Two months before the pandemic, she joined UCLA, where she leads the Quantum Biology Tech (QuBiT) Lab.
2
Oct '23
In-person
+ Online
+ Online
Rochester Institute of Technology
Mishkat Bhattacharya
Optical Tweezer Phonon Laser
Abstract:
In this talk I will describe our recent theoretical work on optomechanics with levitated nanoparticles. I will address cooling and regenerative center-of-mass motion (phonon lasing) theory in relation to the experiments in the group of our collaborator A. N. Vamivakas at the University of Rochester.
[1] S. Sharma, A. Kani and M. Bhattacharya, Phys. Rev. A 105, 043505 (2022)
[2] R. M. Pettit, W. Ge, P. Kumar, D. R. L.-Martin, J. T. Schulz, L. P. Neukirch, M. Bhattacharya and A. N. Vamivakas, Nature Photonics 13, 372 (2019)
[1] S. Sharma, A. Kani and M. Bhattacharya, Phys. Rev. A 105, 043505 (2022)
[2] R. M. Pettit, W. Ge, P. Kumar, D. R. L.-Martin, J. T. Schulz, L. P. Neukirch, M. Bhattacharya and A. N. Vamivakas, Nature Photonics 13, 372 (2019)
10
Oct '23
In-person
+ Online
+ Online
City College, CUNY
Vinod Menon
Half-light half-matter quasiparticles: from condensation to quantum nonlinearity
Abstract:
Strong light-matter interaction results in the formation of half-light half-matter quasiparticles called polaritons that take on the properties of both its constituents. In this talk I will first introduce the concept of strong light-matter coupling in low-dimensional semiconductors in optical cavities. Following this, I will discuss the formation of Bose Einstein like condensates at room temperature using polaritons formed in organic molecules1. Approaches to create condensate lattices in such systems will also be presented. Next, I will present our recent work on polaritons in 2D materials and their potential to reach quantum nonlinearity2. I will conclude with a discussion on the potential of strong light-matter coupling to engineer magneto-optic response of 2D materials3,4.
1. Deshmukh, P. et al. A plug-and-play molecular approach for room temperature polariton condensation. ArXiv 2304.11608 (2023).
2. Datta, B. et al. Highly nonlinear dipolar exciton-polaritons in bilayer MoS2. Nature Communications 2022 13:1 13, 1–7 (2022).
3. Dirnberger, F. et al. Spin-correlated exciton–polaritons in a van der Waals magnet. Nature Nanotechnology 2022 17:10 17, 1060–1064 (2022).
4. Dirnberger, F. et al. Magneto-optics in a van der Waals magnet tuned by self-hybridized polaritons. Nature 620, 533–537 (2023).
1. Deshmukh, P. et al. A plug-and-play molecular approach for room temperature polariton condensation. ArXiv 2304.11608 (2023).
2. Datta, B. et al. Highly nonlinear dipolar exciton-polaritons in bilayer MoS2. Nature Communications 2022 13:1 13, 1–7 (2022).
3. Dirnberger, F. et al. Spin-correlated exciton–polaritons in a van der Waals magnet. Nature Nanotechnology 2022 17:10 17, 1060–1064 (2022).
4. Dirnberger, F. et al. Magneto-optics in a van der Waals magnet tuned by self-hybridized polaritons. Nature 620, 533–537 (2023).
30
Oct '23
In-person
+ Online
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Oakland University
Evgeniy Khain
Intriguing dynamics in a dense cell monolayer
Abstract:
In this talk, we consider an expansion of a dense monolayer of cells: a collective multicellular phenomenon, where cells divide, grow, and maintain contacts with their neighbors. During migration, cells display complex behavior, adjusting both their division rate and their growth after division to the local mechanical environment. Experimental observations show that cells near the edge of the expanding monolayer are larger and move faster than cells deep inside the colony. To explain these observations and describe cell migration patterns, we formulate a spatio-temporal theoretical model for multicellular dynamics in terms of the cell area distribution; the model includes cell growth after division and effective pressure. Numerical simulations of the model predict both the speed of invasion and the width of the outer proliferative rim; these predictions are in a good agreement with experimental observations. Theoretical analysis yields the equation for density of cells and reveals a novel type of propagating front with compact support. The velocity of front propagation (monolayer expansion) is obtained analytically and its dependence on all the relevant parameters is determined.
13
Nov '23
In-person
+ Online
+ Online
University of Maryland, College Park
Carlos Ríos Ocampo
Nonvolatile programmable photonics
20
Nov '23
In-person
+ Online
+ Online
Museum of Natural History
Isabel Colman
Empirical approaches to the stellar age-rotation connection in the era of Big Data
Abstract:
Fifty years ago, astronomers discovered a relationship between stellar age and rotation: as stars grow older, they lose angular momentum and "spin down" — or, their rotation period gradually increases. Twenty years ago, the term "gyrochronology" was introduced to describe the metholodology of using a star's rotation period to determine its age. Empirical gyrochronology has to account for the peculiarities of individual stars, and has so far proved that there's no one-size-fits-all relation — but with more data, we can probe more regions of parameter space. Ten years ago, NASA's Kepler mission ended, providing the stellar astrophysics community with four-year continuous time series photometry for over 100,000 stars in one area of the sky. The data from Kepler opened up the study of gyrochronology, but also necessitated the development of new methods for rotation period detection and analysis. With data from ensuing missions K2 and TESS, opportunities to test gyrochronology have blossomed, and the challenges of this analysis have grown more complex. In this talk, I'll cover the history and foundations of gyrochronology, the state of the field, and my work developing software for detecting and classifying stellar rotation in data from the TESS mission.
11
Dec '23
Next Event
In-person
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University of Connecticut
Bahram Javidi
Automated Disease Identification with Multidimensional Optical Imaging
This talk is accessible via Zoom or use
meeting ID 829 2687 2594 and passcode 866995 to join
Abstract:
This seminar is an overview of recent and reported research in rapid automated disease identification with low-cost field portable bio-photonics systems through the analysis of blood cells using multidimensional digital holographic systems. Statistical and/or deep learning algorithms are used to analyze the spatial and temporal characteristics of the reconstructed blood cells for automated disease identification. Recent applications of digital holography and dedicated algorithms for rapid COVID-19 detection will be presented. We present a variety of bio-photonics sensors including 3D printed thin lensless sensors using pseudo-random phase encoding. Conventional holographic systems require a stable optical table for reliable performance. Self-referencing holographic systems show much greater stability and are field portable. Experimental results are presented to illustrate the performance of these instruments in the field such as health clinics for COVID-19 detection, Sickle Cell disease detection, etc. Dedicated algorithms to inspect and classify cells such as blood cells using field portable holographic systems for automated disease identification will be presented. Recent advances in the proposed bio-photonics sensors give this approach agreat potential for success.
Bio:
Prof. Bahram Javidi is Board of Trustees Distinguished Professor at University of Connecticut. His interests are in a broad range of transformative imaging approaches using optics and photonics, and he has made seminal contributions to passive and active multidimensional imaging from nano to micro and macro scales. His recent research activities include digital holography, polarimetric 3D imaging at low light, 3D visualization and recognition of objects in photon-starved environments; automated disease identification using biophotonics with compact digital holographic sensors for use in developing countries; and optical cyber physical security. He has 35 patents some of which have been licensed by industry. He has been awarded The Optica (OSA) Emmett Leith medal (2021), Optica C. E. K. Mees Medal (2019), and Optica Joseph Fraunhofer Award / Robert M. Burley Prize (2018); The IEEE Photonics Society William Streifer Scientific Achievement Award (2019); and the European Physical Society (EPS) Prize for Applied Aspects of Quantum Electronics and Optics (2015). He was awarded the IEEE Donald G. Fink Paper Prize (2008); the John Simon Guggenheim Foundation Fellow Award (2008); the Alexander von Humboldt Foundation Prize (2007); the SPIE Technology Achievement Award (2008); and the SPIE Dennis Gabor Award (2005). He was named an IEEE Photonics Society Distinguished Lecturer in 2004 and 2005; and was the 2010 recipient of the George Washington University's Distinguished Alumni Scholar Award. He has been named Fellow of IEEE, OSA, SPIE, AIMBE, National Academy of Inventors, and Inst. of Physics.