Thursday, September 29, 2016, 10:00 am

Hosted by: 'Xin Qian'

The J-PARC E34 experiment aims to measure the anomalous magnetic moment (g-2) and electric dipole moment (EDM) of the positive muon with a novel technique utilizing an ultra-cold muons accelerated to 300 MeV/c and a 66 cm-diameter compact muon storage ring without focusing electric field. This measurement will be complementary to the previous BNL E821 experiment and upcoming FNAL E989 experiment with the muon beam at the magic momentum 3.1GeV/c in a 14 m-diameter storage ring. In this talk, I'd like to discuss the present status and prospects.

Thursday, September 29, 2016, 3:00 pm

Hosted by: '''Anze Slosar'''

Understanding structure formation is one of the most important issues in modern cosmology. In particular, in the era of big astronomical data, connecting observation and theory is crucial to improve precision cosmology, and possibly probe new physics. The observables of large-scale structure, such as galaxy number density, generally depend on the density of the environment. This dependence can traditionally be studied by performing gigantic cosmological N-body simulations and measuring the observables in different density environments. Alternatively, we can perform so-called ``separate universe simulations,'' in which the effect of the environment is absorbed into the change of the cosmological parameters. In other words, an overdense universe is equivalent to a positively curved universe, and the structure formation would change accordingly. In this talk, I will introduce the separate universe mapping, and present how the power spectrum and halo mass function changes in different density environments, which are related to the squeezed-limit bispectrum and the halo bias, respectively. I will also discuss our recent progress on extending this approach to multiple fluids such as dynamic dark energy and massive neutrinos.

Friday, September 30, 2016, 10:00 am

Hosted by: ''Xin Qian''

Daya Bay recently updated the light sterile neutrino searching results with 621 days of data. The new analysis has 3.6 times of statistics, improved energy calibration as well as the reduced backgrounds compared to the previous publication. The resulting limits on sin22theta14 are improved by approximately a factor of two over previous results and constitute the most stringent constraints to date in the Delta m2_41 < 0.2 eV2 region. The result is combined with those from MINOS and Bugey-3 experiments to constrain oscillation into light sterile neutrinos. The three experiments are sensitive to complementary regions of parameter space, enabling the combined analysis to probe regions allowed by the LSND and MiniBooNE experiments in 3+1 neutrino framework. Stringent limits on sin22theta_mue are set over six orders of magnitude in the sterile mass-squared splitting Delta m2_41. In this talk, I will show details of the recent update sterile neutrino search at Daya Bay, the reproduction of Bugey-3's results and the combination of Daya Bay, Bugey-3 and MINOS results.

Friday, September 30, 2016, 11:00 am

Hosted by: 'Robert McGraw'

Field measurements in the recent past have shown that secondary organic aerosol (SOA) particles are often amorphous glasses or highly viscous liquids under dry and/or cold conditions. Chemical and physical processes occurring in the interior of the aerosol particle and at the gas/particle interface are influenced by the viscous state in which condensed-phase diffusion is slows down considerably. I will discuss measurements of water diffusion in single, levitated aerosol particles for a number of model systems of SOA. In particular, I will show how Mie-resonance spectroscopy allows to "image" diffusion fronts within these particles and discuss atmospheric implications of kinetic limitations of water uptake.

Friday, September 30, 2016, 12:15 pm

Hosted by: 'Christoph Lehner'

Friday, September 30, 2016, 2:00 pm

Hosted by: 'Kerstin Kleese van Dam'

Linked Science is the practice of inter-connecting scientific assets by publishing, sharing and linking scientific data and processes in end-to-end loosely coupled workflows that enable the sharing and re-use of scientific data. Linked science relies on provenance, curation, and preservation for obtaining reproducible results and sharing datasets for re-use. Many scientific questions are addressed by using data that live in numerous data centers and archives that do not expose their content directly to search engines. A researcher must perform searches on numerous sites, using queries based on multiple metadata schemas, and access data from heterogeneous sources in order to find the data they need to answer scientific questions. We will present a semantic service to enhance the discoverability of datasets in earth science data archives and how it is used in a Linked Science scenario related to the discovery of datasets for a climate change study. We also present how the applicability of this service is expanded by the deployment of an ontology repository and the creation of mappings between ontology entities to link various annotations. Linked ontology entities provide new annotations for datasets. When datasets are better annotated with more granular descriptions, they can be discovered, accessed and operationalized by workflows for numerous provenance and other tasks. This work demonstrates that the use of ontologies—even lightweight ones—provides a path for helping domain experts find the information that they need from heterogeneous datasets for use in complex multi-disciplinary studies, builds better trust in results, and works toward improved reproducibility.

Friday, September 30, 2016, 4:00 pm

The Lab community is invited to attend the 2016 Gertrude Scharff-Goldhaber Award Event. Kathryn Meehan, the 2016 Goldhaber Award recipient will make her presentation by Skype. Featured speakers include Alfred (Fred) Scharff Goldhaber (son of Gertrude), who is a Professor at the C.N. Yang Institute for Theoretical Physics at Stony Brook University. Fred will be speaking about his mother's career as a woman scientist, particularly here at BNL, and of her participation in the formation of Brookhaven Women in Science and other programs at BNL that still thrive today. In addition we will have Camille van der Watt who will talk about her experiences attending the Lab-sponsored SciComp-100 Workshop this summer. A reception will be held following the award ceremony in honor of Gertrude Scharff-Goldhaber and all the participants

Monday, October 3, 2016, 2:00 pm

Hosted by: 'Percy Zahl'

Despite the evolution of scanning probe microscopy (SPM) into a powerful set of techniques that image surfaces and map their properties down to the atomic level, significant limitations in both imaging and mapping persist. Currently, typical SPM capabilities qualitatively record only one property at a time and at a fixed distance from the surface. Furthermore, the probing tip's apex is chemically and electronically undefined, complicating data interpretation. To overcome these limitations, we have started to integrate significant extensions to existing SPM approaches. First, we expanded noncontact atomic force microscopy with atomic resolution to three dimensions by adding the capability to quantify the tip-sample force fields near a surface with picometer and piconewton resolution [1, 2]. Next, we gained electronic information by recording the tunneling current simultaneously with the force interaction [3] and introduced a new operating scheme called tuned-oscillator atomic force microscopy that substantially improved imaging robustness and therefore sample throughput and user friendliness [4]. Finally, we will illustrate how the tip chemistry, tip asymmetry, and tip-sample distance influence the recorded interactions – and thus the information one can gain from images –, ultimately allowing to selectively image specific atomic species [3, 5]. During the talk, applications to various model systems including oxides, metals, ionic crystals, and layered materials will be presented. [1] B. J. Albers et al., Nature Nanotechnology 4, 307 (2009). [2] M. Z. Baykara et al., Advanced Materials 22, 2838 (2010). [3] M. Z. Baykara et al., Physical Review B 87, 155414 (2013). [4] O. E. Dagdeviren et al, Nanotechnology 27, 065703 (2016). [4] H. Mönig et al., ACS Nano 7, 10233 (2013). Host: Percy Zahl

Tuesday, October 4, 2016, 9:00 am

Hosted by: 'Ketevi A. Assamagan, Mary Bishai and Hooman Davoudiasl'

Dates: October 4-7, 2016. Time: 9:00-18:00 on October 4-6, 2016 and 9:00-12:30 on October 7. Place: Physics Department Large Seminar Room. As part of this workshop, on Tuesday October 4th at 3:30pm: BSA lecture on Dark Interactions in Berknar Hall. Wednesday October 5 at 18:30. Workshop Dinner. Please contact Linda at feierabe@bnl.gov to register for the dinner. For more details about this workshop, see the workshop website:

Tuesday, October 4, 2016, 12:00 pm

(Rain date Oct 10) New this year! A friendly inter DOE Lab competition for the 1st mile. Timed Event. DOE sites with the highest proportion of participants and shortest times will win. Pre-registration is required at the web link. Meet at Bldg 438 walk along Brookhaven Ave to the Weather Station and back. Contact healthfest@bnl.gov if any questions.

Tuesday, October 4, 2016, 4:00 pm

Hosted by: ''Peter Wanderer''

Where do we come from? Science is making progress on this age-old question of humankind. The Universe was once much smaller than the size of an atom. Small things mattered in the small Universe, where quantum physics dominated the scene. To understand the way the Universe is today, we have to solve remaining major puzzles. The Higgs boson that was discovered recently is holding our body together from evaporating in a nanosecond. But we still do not know what exactly it is. The mysterious dark matter is holding the galaxy together, and we would not have been born without it. But nobody has seen it directly. And what is the very beginning of the Universe?

Tuesday, October 4, 2016, 5:00 pm

Preliminary Rounds - Bldg 317 (downstairs main room) To register, please email Mike McGuigan at mcguigan@bnl.gov

Wednesday, October 5, 2016, 11:00 am

Pre-registration recommended for the 10 min massages at: http://intranet.bnl.gov/healthfest (11am-2pm) There will be: Ergonomic display, OMC display on Zika, FLU etc, Radiology Imaging, Audiologist, Organ Donor information, Intro to Weight Watchers, LI Blood Services. Room D: Health Screening-Biometrics, cholesterol and Blood sugar by AETNA (11am-1pm)

Wednesday, October 5, 2016, 1:00 pm

Hosted by: ''''Gabi Kotliar''''

In my talk I will present the numerical renormalization group (NRG) as a viable multi-band impurity solver for dynamical mean-field theory (DMFT). NRG offers unprecedented real-frequency spectral resolution at arbitrarily low energies and temperatures. It is thus perfectly suited to study "Hund metals" [1], which show - in experiments and theoretical DMFT calculations - puzzling behavior at unusually low energy scales, like Fermi-liquid behavior at low temperatures, a coherence-incoherence crossover with increasing temperature [2, 3] and fractional power laws for the imaginary part of the Matsubara self-energy in the incoherent regime, discovered already early on with continuous time quantum Monte Carlo (CTQMC) as DMFT solver [3]. I will explicitly demonstrate the advantages of NRG+DMFT in the context of a channel-symmetric three-band Anderson-Hund model on a Bethe lattice at 1/3 filling (with NRG exploiting the non-abelian SU(3) channel symmetry to reduce numerical costs) [4]. In contrast to CTQMC, our NRG+DMFT calculations finally settled the existence of a Fermi-liquid ground state. We further revealed new important insights: our real-frequency one-particle spectral function shows a coherence-incoherence crossover (driven by Hund J rather than Hubbard U) and strong particle-hole asymmetry, which leads to the above-mentioned apparent fractional power laws; two-stage screening, where spin screening occurs at much lower energies than orbital screening ("spin-orbital separation"); and zero-temperature spectral properties that are similar with or without DMFT self-consistency, in contrast to Mott-Hubbard systems, where the DMFT self-consistency opens a gap. A recent reformulation of NRG, called "interleaved NRG" (iNRG) [5, 6] allows to tackle more realistic models of Hund metals where channel symmetries are generally broken (for example, due to crystal field splitting).

Thursday, October 6, 2016, 9:00 am

Hosted by: 'Michael Begel'

Thursday, October 6, 2016, 11:00 am

Hosted by: ''Eric Stach''

Metal-semiconductor hybrid nanoparticles (NPs) have synergistic properties that have been exploited in photocatalysis, electrical, and optoelectronic applications. Rational design of hybrid NPs requires the knowledge of the underlying mechanisms of diffusion of the metal species through the nanoscale semiconductor lattice. One extensively studied process of diffusion of two materials across the nanoparticle surface is known as the nanoscale Kirkendall effect. There, an atomic species A with the lower diffusion rate enters the nanocrystal slower than the B species diffusing from the nanocrystal outward. As a result, voids are formed in B, providing an interesting avenue for making hollow nanocrystals. We used time-resolved X-ray absorption fine-structure spectroscopy, X-ray diffraction and electron microscopy to monitor the diffusion process of Au atoms through InAs nanocrystals in real time. In this system the diffusion rate of the inward diffusing species (Au) is faster than that of the outward diffusion species (InAs), which results in the formation of a crystalline metallic Au core surrounded by an amorphous, oxidized InAs shell with voids in it. These observations indicate that in hybrid Au-InAs NPs the rarely observed "reversed nanoscale Kirkendall effect" is in play. It presents a potentially new way to synthesize unique nanoscale core-shell structures.

Thursday, October 6, 2016, 12:30 pm

Hosted by: 'Hiroshi Oki'

Thursday, October 6, 2016, 4:00 pm

Hosted by: '''Mircea Cotlet'''

Friday, October 7, 2016, 11:00 am

Hosted by: ''Ian Robinson''

Bragg coherent diffractive imaging is an emerging x-ray imaging technique capable of resolving both defect and ultrafast dynamics in nanocrystals with three-dimensional detail and nanometer resolution. This ability to study single nanocrystals in their reactive environments opens new insight into a broad range of materials science questions, including how to improve materials that convert heat into electricity, understanding degradation in advanced battery cathodes, and probing the structure-stability relationship in fuel cell catalysts. Here I will discuss Bragg CDI studies of phonon dynamics in Zinc Oxide and defect dynamics in thin film grains driven by temperature. Finally, I will touch on future directions for BCDI with the anticipated increase in coherent flux at upgraded synchrotrons.

Wednesday, October 12, 2016, 2:00 pm

Hosted by: ''Pier Paolo Giardino''

Thursday, October 13, 2016, 12:30 pm

Hosted by: 'Hiroshi Oki'

Thursday, October 13, 2016, 6:30 pm

Hosted by: ''Nora Sundin''

Wednesday, October 19, 2016, 2:30 pm

Thursday, October 20, 2016, 12:30 pm

Hosted by: 'Hiroshi Oki'

Thursday, October 20, 2016, 3:00 pm

Hosted by: 'Xin Qian'

Gaseous Electron Multiplier (GEM) detectors have been widely studied and applied in many experiments. The so called zigzag readout has been studied for reading out large area GEM detectors for tracking purposes. Using of the zigzag readout can significantly reduce number of electronic channels and hence the cost of a detector while still preserving good spatial resolution on a detector. In this presentation, I will first briefly review the GEM detectors and their applications, then I will focus on the R&D activities on GEM detectors with zigzag readout for tracking at a future electron ion collider (EIC), I'll also cover some potential applications of large area GEM detectors and the zigzag readout for other experiments.

Wednesday, October 26, 2016, 2:00 pm

Hosted by: 'Pier Paolo Giardino'

Friday, October 28, 2016, 2:00 pm

Hosted by: 'Heikki Mantysaari'

Wednesday, November 2, 2016, 2:00 pm

Hosted by: 'Mattia Bruno'

Friday, November 4, 2016, 11:00 am

Hosted by: ''Ian Robinson''

TBA

Monday, November 7, 2016, 4:00 pm

Hosted by: ''Mircea Cotlet''

Understanding the elementary steps in acid-base and metal catalyzed organic transformations is a key for sustainable chemical conversions. Solid acids and bases with nano-pores such as zeolites act as solid Brønsted and Lewis acids, widely used as catalysts with well-defined acid-base sites and a well-defined reaction space around the sites. Within the pores of molecular sieves reacting molecules are constrained in a reaction space, which can be subtly adjusted via direct synthesis, as well as via the addition of cations, oxidic clusters or organic fragments. The impact of such changes on mono- and bimolecular reactions such as elimination reactions of alcohols, cracking and alkylation of hydrocarbons are discussed for gas and liquid phase reactions. Experimental methods to define the state of the reacting molecules combined with detailed kinetic analysis and theory will be used to explain the principal contributions of the interactions and the confinement to determine reaction rates. It will be discussed how reaction rates and pathways can be tailored using the space available for a transition state and the chemical constituents around the active site.

Wednesday, November 9, 2016, 1:30 pm

Hosted by: 'Neelima Sehgal'

Wednesday, November 9, 2016, 2:00 pm

Hosted by: 'Pier Paolo Giardino'

Thursday, November 10, 2016, 11:00 am

Hosted by: 'Robert McGraw'

Mixed-phase clouds are comprised of both liquid droplets and ice crystals. For a given total water content, mixed-phase clouds with higher liquid water contents are optically thicker and therefore more reflective to sunlight compared to those with higher ice water contents. This is due to the fact that liquid droplets tend to be smaller in size and more abundant than ice crystals in Earth's atmosphere. Given the ubiquity of mixed-phase clouds, the ratio of liquid to ice in these clouds is expected to be important for Earth's radiation budget. We determine the climatic impact of thermodynamic phase partitioning in mixed-phase clouds by using five pairs of simulations run with CAM5/CESM. Of the five pairs of simulations, the thermodynamic phase partitioning of two of the simulations were constrained to better agree with observations from CALIPSO. The other three pairs of simulations include a control simulation, as well as an upper and lower bound simulation with maximally high and low amounts of mixed-phase cloud liquid fractions. An analysis of the simulations shows that a negative "cloud phase feedback" that occurs due to the repartitioning of cloud droplets and ice crystals under global warming is weakened when mixed-phase clouds initially contain a higher amount of liquid. Simulations that exhibited weaker cloud phase feedbacks also had higher climate sensitivities. The results suggest that an unrealistically strong cloud phase feedback leading to lower climate sensitivities may be lurking in the many climate models that underestimate mixed-phase cloud liquid fractions compared to observations.

Thursday, November 10, 2016, 1:30 pm

Hosted by: 'Anze Slosar'

Thursday, November 10, 2016, 6:30 pm

Hosted by: 'Nora Sundin'

Wednesday, November 16, 2016, 2:00 pm

Hosted by: 'Amarjit Soni'

Thursday, November 17, 2016, 3:00 pm

Hosted by: 'Anze Slosar'

Current (e.g. DES) and future (e.g. LSST, Euclid) experiments aim to convert multiband images of the sky into precise constraints on cosmological models, neutrino masses, and modifications of general relativity. This standard path for this inference involves making point estimates of the galaxies' redshifts (from observed colors) and weak gravitational lensing distortions (from observed morphologies), then combining these into various cross-correlations and other summary statistics that are compared to numerical simulations of the Universe. These estimators require a slew of empirical corrections to various biases, and have yet to demonstrate accuracies sufficient to reduce biases below systematic errors. I describe two steps to greatly simplify this process and eliminate the need for simulation-based calibration of estimators: first, a practical means to estimate the joint posterior probability of a galaxies' redshift and line-of-sight lensing; second, a method to sample from the posterior distribution of all mass distributions and cosmologies conditional on the galaxy density and lensing data. The main advantages of the new scheme include improved lensing and photo-z accuracy (to the required part-per-thousand level), recovery of non-Gaussian information that is lost in the usual 2-point summary statistics, and correct propagation of uncertainties (including photo-z uncertainties) into the cosmological inferences.

Tuesday, November 29, 2016, 3:30 pm

Hosted by: 'Rob Pisarski'

Wednesday, November 30, 2016, 2:00 pm

Hosted by: 'Mattia Bruno'

Thursday, December 1, 2016, 8:00 am

Hosted by: 'Andrei Nomerotski'

Thursday, December 1, 2016, 9:30 am

Hosted by: 'Long Island Blood Services'

Friday, December 2, 2016, 8:00 am

Hosted by: 'Andrei Nomerotski'

Wednesday, December 7, 2016, 2:30 pm

Thursday, December 8, 2016, 6:30 pm

Hosted by: 'Nora Sundin'

Wednesday, December 14, 2016, 2:00 pm

Hosted by: 'Pier Paolo Giardino'

Thursday, January 12, 2017, 6:30 pm

Hosted by: 'Nora Sundin'

Thursday, February 9, 2017, 6:30 pm

Hosted by: 'Nora Sundin'

Thursday, March 9, 2017, 6:30 pm

Hosted by: 'Nora Sundin'

Thursday, April 13, 2017, 6:30 pm

Hosted by: 'Nora Sundin'

Thursday, May 11, 2017, 6:30 pm

Hosted by: 'Nora Sundin'

Thursday, June 8, 2017, 6:30 pm

Hosted by: 'Nora Sundin'