Multiplexed long-range electrohydrodynamic transport and nano-optical trapping with cascaded bowtie photonic crystal cavities

Photonic crystal cavities have been widely studied for optical trapping due to their ability to generate high quality factor resonances. However, prior photonic crystal nanotweezers possess mode volumes significantly larger than those of plasmonic nanotweezers, which limit the gradient force. Additionally, they also suffer from low particle capture rates. In this paper, we propose a nanotweezer system based on a 1D bowtie photonic crystal nanobeam that achieves extreme mode confinement and an electromagnetic field enhancement factor of 68 times, while supporting a high-quality factor of 15,000 in water. Furthermore, by harnessing the localized heating of a water layer near the bowtie cavity region, combined with an applied alternating current electric field, our system provides long-range transport of particles with average velocities of 5 ${\mu}$m/s towards the bowtie cavities on demand. Once transported to the bowtie cavity region, our results show that a 20 nm quantum dot will be confined in a potential well with a depth of 35 ${k_B}$T. Thus, our approach effectively addresses the challenge of limited capture rate in photonic crystal nanotweezers for the first time. Finally, we present the concept of multiplexed long-range transport for hand-off of a single emitter from one cavity to the next by simply switching the wavelength of the input light. This novel multiplexed integrated particle trapping platform is expected to open new opportunities in directed assembly of nanoscale quantum emitters and ultrasensitive sensors for single particle spectroscopy.Comment: 11 pages, 4 figure

Insider access: pepducin symposium explores a new approach to GPCR modulation

The inaugural Pepducin Science Symposium convened in Cambridge, Massachusetts on March 8-9, 2009 provided the opportunity for an international group of distinguished scientists to present and discuss research regarding G protein-coupled receptor-related research. G protein-coupled receptors (GPCRs) are, arguably, one of the most important molecular targets in drug discovery and pharmaceutical development today. This superfamily of membrane receptors is central to nearly every signaling pathway in the human body and has been the focus of intense research for decades. However, as scientists discover additional properties of GPCRs, it has become clear that much is yet to be understood about how these receptors function. Everyone agrees, however, that tremendous potential remains if specific GPCR signaling pathways can be modulated to correct pathological states. One exciting new approach to this challenge involves pepducins: novel, synthetic lipopeptide pharmacophores that modulate heptahelical GPCR activity from inside the cell membran

Measurement of the sum of WW and WZ production with W+dijet events in pp collisions at sqrt(s) = 7 TeV

A measurement of the inclusive WW+WZ diboson production cross section in proton-proton collisions is reported, based on events containing a leptonically decaying W boson and exactly two jets. The data sample, collected at sqrt(s) = 7 TeV with the CMS detector at the LHC, corresponds to an integrated luminosity of 5.0 inverse femtobarns. The measured value of the sum of the inclusive WW and WZ cross sections is sigma(pp to WW+WZ) = 68.9 +/- 8.7 (stat.) +/- 9.7 (syst.) +/- 1.5 (lum.) pb, consistent with the standard model prediction of 65.6 +/- 2.2 pb. This is the first measurement of WW+WZ production in pp collisions using this signature. No evidence for anomalous triple gauge couplings is found and upper limits are set on their magnitudes