# 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

8

Feb '16

Sergey Vitkalov - Monday, February 8, 2016

Joule heating in systems with discrete spectra

City College of CUNY

ABSTRACT: The quantization of electron motion in magnetic fields generates a plethora of fascinating phenomena observed in condensed materials. One of the well-known examples is the Shubnikov-de Haas (SdH) resistance oscillations. In two dimensional electron systems, SdH oscillations can be very pronounced leading to the Quantum Hall Effect (QHE) at low temperatures.

Landau quantization produces a remarkable effect on Joule heating of two dimensional (2D) electrons. The heating forces 2D electrons into exotic electronic states in which voltage (current) does not depend on current (voltage). In contrast to the linear response at low temperatures (SdH, QHE), the quantization affects Joule heating in a significantly broader temperature range. At temperatures significantly exceeding the cyclotron energy the dc heating produces a multi-tiered electron distribution containing as many tiers as the number of Landau levels inside the energy interval kT. This quantal heating preserves the overall broadening of the electron distribution. Surprisingly the distribution resulting from quantal heating is, in some respect, similar to the one created by the quantum microwave pumping between Landau levels. Indicated phenomena produce a broad variety of nonlinear effects in quantizing magnetic fields and present an exciting area of the contemporary research. In this talk a recent experimental investigations of the dynamics of quantal heating are presented indicating an important role of the electron-electron interaction in the relaxation of the electron distribution.

Landau quantization produces a remarkable effect on Joule heating of two dimensional (2D) electrons. The heating forces 2D electrons into exotic electronic states in which voltage (current) does not depend on current (voltage). In contrast to the linear response at low temperatures (SdH, QHE), the quantization affects Joule heating in a significantly broader temperature range. At temperatures significantly exceeding the cyclotron energy the dc heating produces a multi-tiered electron distribution containing as many tiers as the number of Landau levels inside the energy interval kT. This quantal heating preserves the overall broadening of the electron distribution. Surprisingly the distribution resulting from quantal heating is, in some respect, similar to the one created by the quantum microwave pumping between Landau levels. Indicated phenomena produce a broad variety of nonlinear effects in quantizing magnetic fields and present an exciting area of the contemporary research. In this talk a recent experimental investigations of the dynamics of quantal heating are presented indicating an important role of the electron-electron interaction in the relaxation of the electron distribution.

29

Feb '16

Katherine Willets - Monday, February 29, 2016

Super-resolution imaging of plasmonic nanostructures

Temple Univesity

ABSTRACT: Noble metal nanoparticles can support localized surface plasmons, which lead to enhanced electromagnetic fields at the nanoparticle surface and allow for a host of surface-enhanced spectroscopies, such as surface-enhanced Raman scattering (SERS). While extensive theoretical calculations have been performed that predict how these enhanced electromagnetic fields are distributed on the nanoparticle surface, confirming these results using optical techniques is extremely challenging due to the diffraction limit of light. Because the metal nanoparticles are smaller than the wavelength of light, they appear as diffraction limited spots in optical images, obscuring the local electromagnetic field enhancements. This talk will describe recent efforts to use high resolution single molecule imaging techniques to measure how electromagnetic fields are locally enhanced on the surface of noble metal nanoparticles for applications in SERS. Single molecule spectroscopy allows us to beat the diffraction limit by over an order of magnitude, providing the necessary resolution to optically image electromagnetic field enhancements on noble metal nanoparticle surfaces.

7

Mar '16

Alexander Gaeta - Monday, March 7, 2016

Extreme Nonlinear Optics on Chip

Columbia University

21

Mar '16

Sumita Pennathur - Monday, March 21, 2016

Electrokinetic Micro- and Nanofluidic Technologies for Quantitative Detection of Viral Nucleic Acids

University of California Santa Barbara

ABSTRACT: Rapidly evolving acute respiratory infectious diseases (for example, Influenza, Severe Acute Respiratory Syndrome (SARS), Middle East Respiratory Syndrome (MERS), and West Nile Flavivirus (WNF)) now have significantly deleterious impacts on human health and economic productivity worldwide. Due to their highly contagious nature, and rapid negative impact on human health and economies, these diseases require developing a simple, high throughput, and immediate (within 30 minutes) screening methodology that can affordably and accurately determine virus diagnosis, so that treatments can be administered in a timely fashion. Furthermore, the expense of anti-virals now prohibits broad distribution even in developed countries. The diagnostic approaches that we are developing in the Pennathur lab enables rapid regionally based deployment of medications to stymie the spread of viruses. These approaches include (1) the development of a nanofluidic conductivity sensor for general nucleic acid detection, (2) fluorescent silver nanocluster DNA probes (AgNC-DNA) combined with microfluidic capillary electrophoresis (mCE), to detect and identify DNA sequences from HepA, HepB and HepC viruses, and (3) microfluidic tangential flow filtration (μTFF) of blood and serum for efficient on-chip sample preparation.

Specifically, we have developed a novel nanofluidic-based platform for the efficient detection of nucleic acids. The transduction method is label-free, inducing the formation DNA complexes that result in changes in flow velocity and current in a nanofluidic channel. This innovation takes into account the changes in surface and bulk conductivity in a nanochannel due to the concentration of ions in the bulk. Furthermore, we have developed a method for modifying a low cost, molecular beacon-like AgNC-DNA probe so that multiple DNA sequences can be detected and identified simultaneously and rapidly using microfluidic capillary electrophoresis. As a demonstration, we used this technique to design probes for nucleic acid targets of Hepatitis A, B and C virus. Finally, to truly make this work translational, we have developed a microfluidic based method for biological sample filtration. Such a method allows for facile integration with the above diagnostic sensors, and uses tangential flow filtration methods to effectively isolate targets of interest.

Specifically, we have developed a novel nanofluidic-based platform for the efficient detection of nucleic acids. The transduction method is label-free, inducing the formation DNA complexes that result in changes in flow velocity and current in a nanofluidic channel. This innovation takes into account the changes in surface and bulk conductivity in a nanochannel due to the concentration of ions in the bulk. Furthermore, we have developed a method for modifying a low cost, molecular beacon-like AgNC-DNA probe so that multiple DNA sequences can be detected and identified simultaneously and rapidly using microfluidic capillary electrophoresis. As a demonstration, we used this technique to design probes for nucleic acid targets of Hepatitis A, B and C virus. Finally, to truly make this work translational, we have developed a microfluidic based method for biological sample filtration. Such a method allows for facile integration with the above diagnostic sensors, and uses tangential flow filtration methods to effectively isolate targets of interest.

28

Mar '16

Steven Anlage - Monday, March 28, 2016

A Wave Chaotic Approach to Understanding Electromagnetic Compatibility

University of Maryland

ABSTRACT: Because of the possibility of electromagnetic interference between neighboring electronic systems, there is an urgent need to quantify the entry and distribution of electromagnetic (EM) energy within complicated metallic enclosures and to understand the manner in which this energy couples to sensitive electronic devices within such enclosures. When the wavelength of the impinging radiation is much smaller than the typical length scale of the enclosure, the distribution of energy within such cavities is highly sensitive to small changes in the frequency, the structure of the cavity, as well as the nature of the channels which couple EM energy into the cavity. Thus, a statistical approach to understanding this problem is called for.

There is great interest in the wave and quantum properties of systems that show chaos in the classical (short wavelength) limit. These ‘wave chaotic’ systems appear in many contexts: nuclear physics, acoustics, two-dimensional quantum dots, and electromagnetic enclosures, for example. Random Matrix Theory (RMT) predicts the universal fluctuating properties of quantum/wave systems that show chaos in the classical/ray limit.

In this context we developed a stochastic model, the “Random Coupling Model” (RCM) [1,2], which can accurately predict the probability density functions (PDFs) of voltages and electromagnetic field quantities on objects within such cavities, given a minimum of information about the cavity and the nature of its internal details. The RCM is formulated in terms of electrical impedance, essentially equivalent to Wigner’s reaction matrix in quantum mechanics, rather than the more commonly studied scattering matrix. The RCM predictions have been tested in a series of experiments using normal metal and superconducting quasi-two-dimensional and three-dimensional electromagnetic billiards [3]. We have extended the RCM in a number of directions, for example by examining the effects of ‘short orbit’ ray trajectories that enter the cavity, bounce a small number of times, and then leave the cavity. We are able to account for the effects of these orbits using a semi-classical theory, and find excellent agreement between theory and experiment [4]. Our current efforts are focused on testing predictions for the statistical properties of multiple inter-connected enclosures [5], enclosures irradiated through apertures [6], and enclosures characterized by a mixed chaotic and regular phase space [7], using scaled model structures.

For more information see: http://anlage.umd.edu/AnlageQChaos.htm.

[1] S. Hemmady, et al., Phys. Rev. Lett. 94, 014102 (2005).

[2] X. Zheng, T. M. Antonsen and E. Ott, Electromagnetics 26, 3 (2006); Electromagnetics 26, 37 (2006).

[3] S. Hemmady, et al., IEEE Trans. Electromag. Compat. 54, 758-771 (2012); Z. B. Drikas, et al., IEEE Trans. Electromag. Compat. 56, 1480-1487 (2014).

[4] J.-H. Yeh, et al., Phys. Rev. E 81, 025201(R) (2010); Phys. Rev. E 82, 041114 (2010).

[5] G. Gradoni, et al., Phys. Rev. E 86, 046204 (2012).

[6] G. Gradoni, et al., IEEE Trans. Electromag. Compat., 57, 1049-1061 (2015).

[7] Ming-Jer Lee, et al., Phys. Rev. E 87, 062906 (2013).

There is great interest in the wave and quantum properties of systems that show chaos in the classical (short wavelength) limit. These ‘wave chaotic’ systems appear in many contexts: nuclear physics, acoustics, two-dimensional quantum dots, and electromagnetic enclosures, for example. Random Matrix Theory (RMT) predicts the universal fluctuating properties of quantum/wave systems that show chaos in the classical/ray limit.

In this context we developed a stochastic model, the “Random Coupling Model” (RCM) [1,2], which can accurately predict the probability density functions (PDFs) of voltages and electromagnetic field quantities on objects within such cavities, given a minimum of information about the cavity and the nature of its internal details. The RCM is formulated in terms of electrical impedance, essentially equivalent to Wigner’s reaction matrix in quantum mechanics, rather than the more commonly studied scattering matrix. The RCM predictions have been tested in a series of experiments using normal metal and superconducting quasi-two-dimensional and three-dimensional electromagnetic billiards [3]. We have extended the RCM in a number of directions, for example by examining the effects of ‘short orbit’ ray trajectories that enter the cavity, bounce a small number of times, and then leave the cavity. We are able to account for the effects of these orbits using a semi-classical theory, and find excellent agreement between theory and experiment [4]. Our current efforts are focused on testing predictions for the statistical properties of multiple inter-connected enclosures [5], enclosures irradiated through apertures [6], and enclosures characterized by a mixed chaotic and regular phase space [7], using scaled model structures.

For more information see: http://anlage.umd.edu/AnlageQChaos.htm.

[1] S. Hemmady, et al., Phys. Rev. Lett. 94, 014102 (2005).

[2] X. Zheng, T. M. Antonsen and E. Ott, Electromagnetics 26, 3 (2006); Electromagnetics 26, 37 (2006).

[3] S. Hemmady, et al., IEEE Trans. Electromag. Compat. 54, 758-771 (2012); Z. B. Drikas, et al., IEEE Trans. Electromag. Compat. 56, 1480-1487 (2014).

[4] J.-H. Yeh, et al., Phys. Rev. E 81, 025201(R) (2010); Phys. Rev. E 82, 041114 (2010).

[5] G. Gradoni, et al., Phys. Rev. E 86, 046204 (2012).

[6] G. Gradoni, et al., IEEE Trans. Electromag. Compat., 57, 1049-1061 (2015).

[7] Ming-Jer Lee, et al., Phys. Rev. E 87, 062906 (2013).

30

Mar '16

Sergey Makarov - Wednesday, March 30, 2016

Recent advances in all-dielectric and hybrid nanophotonics

ITMO University, Saint Petersburg

ABSTRACT: The resonant metallic nanoparticles are proven to be efficient systems for the electromagnetic field control at nanoscale, owing to the ability to localize and enhance the optical field via excitation of strong plasmon resonances. In turn, high refractive index dielectric nanoparticles with low dissipative losses in the visible range, possessing magnetic and electric Mie-type resonances, offer great opportunity for light control via designing of scattering properties. Such resonant nanoparticles made of high refractive index dielectrics (Si, Ge etc.) revolutionized the field of nanophotonics, opening a new branch – All-dielectric Nanophotonics. In this talk, we will discuss recent advances in the all-dielectric and hybrid (metal/dielectric) nanophotonics, including such effects as nonlinear reconfiguration of nanoparticle scattering properties and enhanced optical frequency conversion. Additionally, I will present our novel methods for fabrication of resonant all-dielectric and hybrid nanoparticles.

4

Apr '16

Hakan Tureci - Monday, April 4, 2016

Dissipative stabilization of many-body states via photon-mediated interactions

Princeton University

11

Apr '16

I. Cevdet Noyan - Monday, April 11, 2016

Information Volume of Diffraction from a Nanoparticle

Columbia University

ABSTRACT: 100-plus years of theoretical and experimental advances have reduced kinematical scattering formalisms for powder diffraction to routine, vendor-supplied, black-box analysis programs accessible to users at all training levels. Understanding what really goes on in the analysis, however, is a non-trivial task. We used computer modeling to analyze the powder diffraction process from nanoparticle ensembles.

Our results showed, surprisingly, that the classical formulations described in diffraction textbooks were inadequate; venerable concepts like reflection multiplicity, the "Lorentz factor", sampling statistics, etc. actually depended on the size of the crystalline particles contributing to the diffraction profile. We expect modeling of scattering experiments to yield more surprises as the phase space hidden behind canonical assumptions becomes accessible for exploration.

Our results showed, surprisingly, that the classical formulations described in diffraction textbooks were inadequate; venerable concepts like reflection multiplicity, the "Lorentz factor", sampling statistics, etc. actually depended on the size of the crystalline particles contributing to the diffraction profile. We expect modeling of scattering experiments to yield more surprises as the phase space hidden behind canonical assumptions becomes accessible for exploration.

18

Apr '16

Michael Shara - Monday, April 18, 2016

The Nova-Supernova Connection

American Museum of Natural History

ABSTRACT: Classical novae and supernovae were long thought to be completely separate astrophysical phenomena. This is no longer true; at least some supernovae may have symbiotic nova precursors. I’ll review the current state of knowledge of the temporal evolution of the white dwarfs in novae, and the Tree of Death of Supernovae. These will help illuminate the still-controversial but ultimately testable, hypothesized connection between novae and supernovae.

2

May '16

Saima Husaini - Monday, May 2, 2016

ABSTRACT: In recent years, graphene has emerged as a potential material in optoelectronic devices ranging from optical modulators, photodetectors to saturable absorbers for mode-locking lasers. Significant effort has also been made to develop graphene-based materials and devices for biotechnological applications such as biosensors, drug delivery, cell imaging and detection.

The aim of this talk is to introduce the optoelectronic properties of graphene and possible applications to various devices. The devices covered will range from nonlinear optical devices such as optical limiters and saturable absorbers for mode-locking lasers, to graphene field effect transistors (FETs) for chemical sensing.

The aim of this talk is to introduce the optoelectronic properties of graphene and possible applications to various devices. The devices covered will range from nonlinear optical devices such as optical limiters and saturable absorbers for mode-locking lasers, to graphene field effect transistors (FETs) for chemical sensing.

9

May '16

Xiaojun Cheng - Monday, May 9, 2016

The density of states in random media

Queens College of CUNY

16

May '16

Garnett Bryant - Monday, May 16, 2016

Designing Nanoscale to Atomic Scale Semiconductor Devices for Quantum Technologies: Atomistic Theory

National Institute of Standards and Technology