Tuesday, October 24, 2017, 11:00 am

Hosted by: 'Bjoern Schenke'

The observation of charge separation induced by the Chiral Magnetic Effect (CME), could provide crucial insights on anomalous transport and the interplay of chiral symmetry restoration, axial anomaly, and gluonic topology in the Quark Gluon Plasma (QGP) produced in heavy ion collisions. I will discuss recent differential charge separation measurements,for p(d)+Au, Au(Cu)+Au and U+U, with a correlator specifically designed to give discernible responses to CME-driven charge separation and non-CME backgrounds. Measurements which span the beam energy range Root_s = 19.5 - 200 GeV will be presented. The d(p)+Au results are observed to be consistent with the reduced magnetic field strength and the essentially random B-field orientations expected in these collisions. In contrast, the Au(Cu)+Au and U+U measurements validate the presence of CME-driven charge separation quantified by the Fourier dipole coefficient a1. Ongoing attempts for CME-signal quantification, as well as implications for the upcoming RHIC isobar run, will be discussed as well.

Tuesday, October 24, 2017, 3:30 pm

Hosted by: 'Peter Petreczky'

On August 17, 2017 the merger of two neutron stars was detected in the form of gravitational-waves by LIGO/Virgo. As a result of over a decade long preparation for multimessenger observations the event was also seen electromagnetically across the full spectrum. The history and future of the multimessenger effort using gravitational-waves will be discussed from an instrumentalist viewpoint.

Wednesday, October 25, 2017, 10:00 am

Hosted by: 'QOL/BERA/Recreation'

Newcomers, individuals, and families are welcome to come to Hospitality Coffee & Play Group each Wednesday at the Rec Hall, Bldg. 317, in the apartment area. If you have children, they will play while the adults socialize.

Wednesday, October 25, 2017, 1:30 pm

Hosted by: '''Cedomir Petrovic'''

Progress in the widespread adoption of all solid heat-to-electricity technologies has largely been hindered by the absence of suitable thermoelectric materials. In pursuit for new thermoelectrics recent advances in large-scale deployment of first principles calculations could be useful in identifying new promising material systems. However, the need to predict electron and phonon transport properties with sufficient accuracy renders direct assessment of the thermoelectric figure of merit (zT) for large numbers of systems unfeasible. This is true even in the case of relatively simple semiconductor materials, which could be described by the computationally inexpensive single particle theories such as density functional theory (DFT). While the state-of-the-art DFT based approaches to charge carrier and heat transport of semiconductors can deliver desired accuracy, they are currently limited to relatively simple chemistries and/or case-by-case studies. In this talk I will discuss integrated theory-computation-experiment efforts in developing a robust set of material descriptors that: (1) are rooted in the Boltzmann transport theory, but do not rely on classic and largely inapplicable constant relaxation time or constant mean free path approximations, (2) are computationally tractable allowing material searches across large chemical spaces, and (3) are sufficiently accurate to provide reliable predictions. Our approach is demonstrated to correctly identify known thermoelectric materials1 and reliably suggest new and promising candidate semiconductors.2 At the end, I will review successes and failures in our quest for new thermoelectrics, and discuss dopability of semiconductors as the critical outstanding challenge in achieving high zT materials. 1. Yan, P. Gorai, B. Ortiz, S. Miller, S. A. Barnett, T. Mason, V. Stevanovic, and E. S. Toberer, "Material descriptors for thermoelectric performance", Energy Environ. Sci. 2. P. Gorai, V. Stevanovic, and E. Tobe

Wednesday, October 25, 2017, 2:30 pm

A variety of cryogenic sensor arrays can be read out by coupling each detector element to a microwave resonator whose resonant frequency changes in response to the physics signal. The use of microfabrication techniques and high Q superconducting resonators allows thousands of sensor elements to be multiplexed in this way, and then simultaneously read out through a single RF cable. The SMuRF electronics provide high dynamic range readout along with flux-ramp drive to reduce 1/f noise, and firmware controlled RF line tracking to reduce system nonlinearities. The hardware design supports up to 4000 sensors operating in a 4-8GHz frequency range in a single ATCA card, allowing compact high density systems. The initial target applications are RF SQUID multiplexed CMB telescopes and energy-resolving X-ray detectors; however the hardware will also support MKID and other cryogenic sensors for cryogenic particle detectors and other applications.

Thursday, October 26, 2017, 12:30 pm

Hosted by: ''Hiromichi Nishimura''

Quarkonium can be used as a probe of quark-gluon plasma (QGP) in heavy ion collisions. The production process is complicated by several factors: plasma screening effect, in-medium dissociation and recombination, cold nuclear matter effect and feed-down contributions. In this talk, I will present a set of Boltzmann transport equations that govern the in-medium evolution of the heavy quark and quarkonium system. The dissociation and recombination rates are calculated from potential non-relativistic QCD at leading order. I will explain how the system reaches equilibrium in a QGP box and show how the system evolves under a boost invariant longitudinal expansion. I will argue that the angular distribution of quarkonium probes the stages at which recombination occurs. The presented framework will be extended in future work to include other factors influencing quarkonium production.

Thursday, October 26, 2017, 3:00 pm

Hosted by: 'Xin Qian'

Coherent elastic neutrino-nucleus scattering (CEvNS) is a process in which a neutrino scatters off an entire nucleus at low momentum transfer, and for which the observable signature is a low-energy nuclear recoil. It represents a background for direct dark matter detection experiments, as well as a possible signal for astrophysical neutrinos. Furthermore, because the process is cleanly predicted in the Standard Model, a measurement is sensitive to beyond-the-Standard-Model physics, such as non-standard interactions of neutrinos. The process was first predicted in 1973. It was measured for the first time by the COHERENT collaboration using the high-quality source of pion-decay-at-rest neutrinos from the Spallation Neutron Source (SNS) at Oak Ridge National Laboratory and a CsI[Na] scintillator detector. This talk will describe COHERENT's recent 6.7-sigma measurement of CEvNS, the status and plans of COHERENT's suite of detectors at the SNS, and future physics reach.

Thursday, October 26, 2017, 4:00 pm

Celebrate the centennial of women's suffrage in New York State. This presentation will include vintage photographs and discussions of various aspects of the movement, focusing on the involvement of Long Island women. Presented by the American Association of University Women (AAUW) Islip Area Branch, the talk features stories of courageous and militant suffragists and their political activism, as well as the activities of the anti-suffragists.

Friday, October 27, 2017, 10:00 am

Hosted by: ''Alessandro Tricoli''

There is an extensive, on-going dark matter search program at the LHC that explores several different types of possible interactions between WIMP-like dark matter and standard model particles. The dark matter searches at the LHC are complementary, and in case of certain models, significantly more sensitive than the direct and indirect dark matter searches. In this talk I will discuss several key dark matter searches being pursued by the CMS collaboration. These cover a wide variety of final states in which dark matter particles are produced in association with one or more energetic, visible objects in the detector resulting in 'MET+X' signatures. Furthermore, I will also discuss the constraints set on dark matter interactions by certain resonance searches.

Wednesday, November 1, 2017, 2:00 pm

Hosted by: 'Sally Dawson'

Thursday, November 2, 2017, 12:30 pm

Hosted by: 'Hiromichi Nishimura'

Thursday, November 2, 2017, 3:00 pm

Hosted by: ''Xin Qian''

The neutron is the simplest nuclear system that can be used to probe the structure of the weak interaction and search for physics Beyond the Standard Model. Measurements of neutron ?-decay observables are sensitive to scalar and tensor interactions in the weak force which are not present in the Standard Model. The lifetime of the neutron ?n is an important parameter for Big-Bang Nucleo-synthesis models, solar fusion models, and absolute neutrino scattering cross-sections, and can be used to test the unitarity of the Cabibbo-Kobayashi-Maskawa quark mixing matrix. Presently, the two typical methods used to measure the neutron lifetime, cold neutron beam measurements and stored ultracold neutron (UCN) measurements, disagree by roughly 4?. This discrepancy motivates the need for new measurements with complementary systematic uncertainties to previous efforts. The UCN? experiment uses an asymmetric magneto-gravitational UCN trap with in situ counting of surviving neutrons to measure the neutron lifetime. Previous bottle experiments confined UCN in a material storage vessel creating a significant correction due to losses resulting from the material UCN interactions. The magnetic and gravitational confinement of the UCN minimizes losses due to material interactions. Additionally, UCN? uses a detection system that is lowered into the storage volume which avoids emptying the surviving UCN into an external detector. This minimizes any possible transport related systematics. This in situ detector also enables counting at various heights in the vessel, which provides information on the trapped UCN energy spectrum, quasi-bound orbits, and possible phase space evolution. I will present the physics motivation for precision neutron physics, a description of the UCN? experiment, the results of data collected during the 2016-2017 accelerator cycle which resulted in a value of τn=877.7±(0.7) stat (+0.3/−0.1) sys in agreement with previous material bottle

Thursday, November 2, 2017, 4:00 pm

Hosted by: ''Chang-Yong Nam''

We have been developing atomic layer deposition (ALD) nanocomposite coatings comprised of conducting, metallic nanoparticles embedded in an amorphous dielectric matrix. These nanocomposite films have proved to be exceptional as resistive coatings in solid-state electron multipliers, as charge drain coatings, and as solar absorbing films in concentrated solar power. All of these applications demand tunable properties so that particular attributes of the film, such as electronic resistivity, can be precisely tailored for maximum efficiency. In our films, the properties are tuned by adjusting the ratio of metallic and dielectric components. For example, nanocomposite films comprised of W:Al2O3 are prepared using alternating exposures to trimethyl aluminum (TMA) and H2O for the Al2O3 ALD and alternating WF6/Si2H6 exposures for the W ALD. By varying the ratio of ALD cycles for the W and the Al2O3 components in the film, we can tune precisely the resistance of these coatings over a very broad range from 1012-105 Ohm-cm. We have used this strategy to synthesize a broad range of ALD nanocomposites combining different metals and dielectrics. These nanocomposite coatings have been utilized to functionalize capillary glass array plates and fabricate large-area microchannel plates suitable for application in large-area photodetectors. In addition, we have applied these films to serve as charge drain coatings in micro electro-mechanical systems (MEMS) devices for a prototype electron beam lithography tool, and obtained high-resolution electron beam patterns without charging artifacts. We have also used these nanocomposite coatings to infiltrate porous scaffolds resulting in selective solar absorbing coatings with high visible absorption and low IR emittance suitable for power tower receivers in concentrated solar power.

Friday, November 3, 2017, 11:00 am

Hosted by: ''Igor Zaliznyak''

Feynman diagrams are the most celebrated and powerful tool of theoretical physics usually associated with the analytic approach. I will argue that diagrammatic expansions are also an ideal numerical tool with enormous and yet to be explored potential for solving interacting many-body systems by direct simulation of Feynman diagrams (bare or skeleton) for the proper self-energies and polarization operators up to high order. Though the original series based on are propagators are sign-alternating and often divergent one can determine the answer behind them by using proper series re-summation techniques and working with skeleton diagrams, i.e. by making the entire scheme self-consistent. The bottom line is that the diagrammatic Monte Carlo approach generically solves the computational complexity for interacting fermionic systems. In terms of physical applications, I will disucss results for the Hubbard model, resonant fermi gas at unitarity, and stability of Dirac liquid against strong Coulomb interaction in graphene.

Friday, November 3, 2017, 2:00 pm

Hosted by: 'Chun Shen'

Monday, November 6, 2017, 1:30 pm

Hosted by: '''Chris Homes'''

Recently we observed an intriguing, magnetic-filed-induced insulator-to-metal transition in YBa2Cu3O7/Pr1-xCaxMnO3 (YBCO/PCMO) multilayers [1]. In the low field regime, the response of these multilayers is highly resistive and resembles the one of granular superconductors or frustrated Josephson-networks. Notably, a coherent superconducting response can be restored with a large magnetic field. The latter also suppresses the charge/orbital order of the PCMO layers towards a ferromagnetic state. This coincidence suggests an intimate relationship between the insulator-to-superconductor transition in the YBCO layer and the suppression of the charge/orbital order in the PCMO. I will discuss the evidence, based on resonant x-ray scattering experiments, that the latter induces (or strongly enhances) a static Cu-CDW order in YBCO that is intertwined with superconductivity. [1] B.P.P. Mallett et al., Phys. Rev. B 94, 180503(R) (2016).

Tuesday, November 7, 2017, 3:30 pm

Hosted by: 'Andrei Nomerotski'

In the first part of our talk we will show how to produce photonic quantum entanglement and how to store it and distribute it by optically manipulating the properties of room temperature atomic clouds. We will discuss our recent experiments in which several quantum devices are already interconnected forming an elementary quantum cryptographic network. We will also discuss our progress regarding the construction of an entanglement sharing link between Stony Brook and BNL. In the second part we will show our progress regarding the construction of an analog quantum computer capable of simulating relativistic dynamics using atoms and quantized light. We will show how our device is already capable of simulating Dirac and Jackiw-Rebbi Hamiltonians as well as the road map towards simulating Quantum Field Theory Hamiltonians.

Wednesday, November 8, 2017, 2:00 pm

Hosted by: 'Sally Dawson'

Thursday, November 9, 2017, 1:30 pm

Hosted by: ''Igor Zaliznyak''

TBD

Thursday, November 9, 2017, 3:00 pm

Hosted by: ''Erin Sheldon''

Thursday, November 9, 2017, 4:00 pm

Hosted by: 'John Hill'

The possibility of out-running radiation damage by the "diffract-and-destroy method, using femtosecond pulses of either electrons or hard X-rays, opens completely new vistas for imaging molecular dynamics at atom resolution and sub-picosecond speeds (1). First, I'll compare high-energy electron beams for this purpose, and compare them in regard to damage mechanisms and time-scales with XFEL radiation. I'll suggest a fast mode of image formation which provides high resolution despite the use of the large incoherent photocathode. I'll then review our work using the hard X-ray pulsed laser at SLAC within our BioXFEL 6-campus NSF consortium (http://www.bioxfel.org), aimed at the application of X-ray lasers (XFELs) to Structural Biology. I'll show molecular movies from light-sensitive proteins with 150 fs time resolution and near-atomic spatial , using both crystals and solution scattering obtained from the LCLS XFEL at SLAC, and very recent single-particle virus images (one virus per shot) showing dynamics. I'll discuss work in my lab on methods for hydrated sample delivery for an XFEL, and the compact IC XFEL under construction on the ASU campus, which uses a laser as an undulator. Finally, I'll review a recent proposal for the use of intensity interferometry to analyze the angular dependence of inner-shell X-ray fluorescence from a molecule. See Google Scholar for references and the many collaborators whom I thank. 1. J.Spence. XFELS for structure and dynamics in biology. IUCrJ 4, 322 (2017).

Thursday, November 9, 2017, 6:30 pm

Monday, November 13, 2017, 1:00 pm

Hosted by: '''Tom Watson'''

Urban dispersion experiments have been extremely useful for development and testing of transport and dispersion models. However, there is an urgent need for improvement of the science of urban transport and validation of the current generation of dispersion models. New, high-resolution data in the multi-scale environment with significant gradients (e.g., land/urban/water) that characterizes major urban areas is necessary to increase accuracy and improve speed of these models as well as to develop model products that specifically meet the needs of the emergency response community. New data are also necessary to design effective real-time meteorological and Chemical, Biological, Radiological, Nuclear (CBRN) monitoring networks necessary to support emergency response and to initialize models. It is timely to design and execute the next generation of Urban Dispersion field programs to address these needs

Tuesday, November 14, 2017, 11:00 am

Hosted by: '''Mike Jensen'''

pending

Tuesday, November 14, 2017, 3:30 pm

Hosted by: ''Rob Pisarski''

Wednesday, November 15, 2017, 2:00 pm

Hosted by: 'Sally Dawson'

Wednesday, November 15, 2017, 2:30 pm

The pair creation energy, w, and Fano factor of silicon were measured using CCD250 and 55Fe X-rays. The measurements were performed at the sensor temperature of 185K. The measured pair creation energy is w = 3.65 +/- 0.009 eV at Mn K_alpha and the Fano factor at this energy is F=0.129 +/- 0.001. We will show that our measurements agree with theory and will be described in detail. The system gain was obtained from flat field exposures using properties of Poisson distribution. The details of our measurement procedure will be presented.

Thursday, November 16, 2017, 12:30 pm

Hosted by: '''Hiromichi Nishimura'''

We present non-perturbative first-principle results for quark-, gluon- and meson 1PI correlation functions of two-flavour Landau-gauge QCD in the vacuum and Yang-Mills theory at finite temperature. They are obtained by solving their Functional Renormalisation Group equations in a systematic vertex expansion, aiming at apparent convergence within a self-consistent approximation scheme. These correlation functions carry the full information about the theory and their connection to physical observables is discussed. The presented calculations represent a crucial prerequisite for quantitative first-principle studies of QCD and its phase diagram within this framework. In particular, we have computed the ghost, quark and scalar-pseudoscalar meson propagators, as well as gluon, ghost-gluon, quark-gluon, quark, quark-meson, and meson interactions and the magnetic and electric components of the gluon propagator, and the three- and four-gluon vertices. Our results stress the crucial importance of the quantitatively correct running of different vertices in the semi-perturbative regime for describing the phenomena and scales of confinement and spontaneous chiral symmetry breaking without phenomenological input. We confront our results for the correlators with lattice simulations and compare our Debye mass to hard thermal loop perturbation theory. Finally, applications to "QCD-enhanced" low-energy effective models of QCD are discussed.

Thursday, November 16, 2017, 1:30 pm

Hosted by: ''Emil Bozin''

TBA

Monday, November 20, 2017, 11:00 am

Hosted by: 'Steve Schwartz'

Earth system models rely on accurate representations of processes and emissions that are evaluated using observations. Iterative refinements are crucial for reliable and robust climate assessments, as I will illustrate with following recent case studies: Carbonaceous aerosol (CA) forcing in current models is prescribed as a balance between the warming by black carbon and the cooling by organic aerosol. However, data show that some organic aerosols called brown carbon absorb sunlight. Furthermore, transparent coatings on black carbon amplify their light absorbing potency by lensing. Such coatings could make black carbon more hydrophilic thereby reducing their lifetime and burden. I will use field and laboratory studies to uncover the fundamental chemistry controlling the optical properties and water affinity of CAs as they age to enable prognostic treatments. Atmospheric carbon dioxide (CO2) accumulation is moderated by its uptake by forests and oceans that soak up 25% each of the human emissions. How carbon sinks will respond to future climate change is uncertain. I will present observations of daily and seasonal variations of column CO2 and CO over the Amazon rainforest. I will show that both biomass burning and net ecosystem exchange that are out of phase control the seasonal CO2 cycle and are captured well by models. However, the daily CO2 drop driven by photosynthesis is biased low in models, a problem that needs to be fixed. Atmospheric Methane (CH4) that accounts for 25% of climate forcing is rising after a long hiatus. Potential causes include leaks from shale gas revolution, intensive agriculture, permafrost thaw, expand wetlands or shorter lifetime by higher Hydroxyl. I will review recent findings and focus on our discovery of the methane hot spot over Four Corners, NM attributed to fossil fuel that demonstrated reported emissions were low by a factor of 3. I will close with our development of an automated neural network methane leak detection

Tuesday, November 21, 2017, 3:30 pm

Hosted by: 'Peter Petreczky'

The recent discovery of gravitational waves by Advanced LIGO ushered in a new kind of astronomy, one potentially integrating its findings with those obtained from electromagnetic and/or neutrino observations. Multi-messenger astronomy promises to revolutionize our understanding of the universe by providing dramatically contrasting views of the same objects. To understand this unprecedented wealth of observational evidence, computer intensive theoretical calculations of the Einstein field equations, coupled with the equations of magneto-hydrodynamics, are required in order to link data with underlying physics. In this talk, I will provide a review on the recent progress in this exciting field of computational astrophysics. With Advanced LIGO now fully operational and the detection of additional gravitational wave events imminent, we expect that there will be a surge in the number of researchers interested in performing simulations of compact binary mergers.

Wednesday, November 29, 2017, 2:00 pm

Hosted by: 'Sally Dawson'

Wednesday, December 6, 2017, 2:00 pm

Hosted by: 'Sally Dawson'

Wednesday, December 6, 2017, 5:00 pm

Please join us for wine, cheese, and conversation with Brookhaven Women in Science (BWIS)—a great opportunity to network, meet new friends, and enjoy the company of friends and colleagues from across the Lab. Discussions will cover the history of BWIS as well as what's to come.

Thursday, December 7, 2017, 4:00 pm

Hosted by: '''Oleg Gang'''

Development of nanostructured materials has introduced revolutionary approaches for materials processing and electronic structure engineering. These materials can offer the advantages of crystalline inorganic solids combined with inexpensive solution-based device fabrication. I will discuss emerging advances in the surface chemistry of semiconducting nanostructures that are poised to enable advances in additive manufacturing of semiconducting and multifunctional materials. Specifically, I will discuss inorganic linkers that permit electronic coupling between the nanocrystals and new semiconducting "solders" that enable solution processing of high-quality inorganic semiconductors. I will also introduce a general chemical approach for photoresist-free, direct optical lithography of functional inorganic nanomaterials (DOLFIN). Examples of patterned materials include metals, semiconductors, oxides, and magnetic and rare earth compositions. No organic impurities are present in the patterned layers, which helps achieve good electronic and optical properties. The conductivity, carrier mobility, dielectric, and luminescence properties of optically patterned layers are on par with the properties of state-of-the-art solution-processed materials. The ability to directly pattern all-inorganic layers using a light exposure dose comparable to that of organic photoresists opens up a host of new opportunities for thin-film device manufacturing.

Wednesday, December 13, 2017, 2:00 pm

Hosted by: 'Sally Dawson'

Thursday, December 14, 2017, 9:15 am

Hosted by: 'Long Island Blood Services'

Thursday, December 14, 2017, 6:30 pm

Thursday, January 11, 2018, 6:30 pm

Thursday, February 8, 2018, 6:30 pm

Tuesday, February 13, 2018, 3:30 pm

Hosted by: 'Peter Petreczky'

On August 17 the LIGO/Virgo gravitational wave observatories detected the first binary neutron star merger event (GW170817), a discovery followed by the most ambitious electromagnetic (EM) follow-up campaign ever conducted. A gamma-ray burst (GRB) of short duration and very low luminosity was discovered by the Fermi and INTEGRAL satellites within 2 seconds of the merger. Within 11 hours, a bright but rapidly-fading thermal optical counterpart was discovered in the galaxy NGC 4993 at a distance of only 40 Mpc. The properties of the optical transient match remarkably well predictions for kilonova emission powered by the radioactive decay of heavy nuclei synthesized in the expanding merger ejecta by the r-process. The rapid spectral evolution of the kilonova emission to near-infrared wavelengths demonstrates that a portion of the ejecta contains heavy lanthanide nuclei. Two weeks after the merger, rising non-thermal X-ray and radio emission were detected from the position of the optical transient, consistent with delayed synchrotron afterglow radiation from an initially off-axis relativistic jet with the properties consistent with those of (on-axis) cosmological short GRB. I will describe a unified scenario for the range of EM counterparts from GW170817 and their implications for the astrophysical origin of the r-process and the properties of neutron stars. I will preview the upcoming era of multi-messenger astronomy, once Advanced LIGO/Virgo reach design sensitivity and a neutron star merger is detected every few weeks.

Thursday, March 8, 2018, 6:30 pm

Thursday, April 12, 2018, 6:30 pm

Thursday, May 10, 2018, 6:30 pm

Thursday, June 14, 2018, 6:30 pm