Document Actions
Posters
For the poster session
LISA Technology
| 1 |
Peter Bender | LISA Studies at the University of Colorado |
| 2 |
Daniel Bindel | Optimized Thruster Control Algorithm for Drag-Free Spacecraft |
| 3 |
Juan José Esteban Delgado | Optical ranging and data transfer development for LISA |
| 4 |
Peter Gath | LISA Mission and System Architectures and Performances |
| 5 |
Martin Gohlke | High Sensitivity Heterodyne Interferometer as a possible Optical Readout for the LISA Inertial Sensor and its Application to Technology Verification |
| 6 |
Hubert Halloin | Iodine laser stabilization for LISA |
| 7 |
Lorenzo Marconi | Ground Based Test for LISA and LISA Pathfinder |
| 8 |
Stephen Merkowitz | Current LISA Spacecraft Design |
| 9 |
Daniele Nicolodi | An improved torsion pendulum for on-ground verification of the LISA gravitational reference sensor |
| 10 |
Kenji Numata | Stabilized interferometry platform for LISA ground testing |
| 11 |
Kenji Numata | Coated fused silica fibers for enhanced sensitivity torsion pendulum for LISA |
| 12 |
Ke-Xun Sun | UV LED Qualification for Space Instrumentation |
| 13 |
Ke-Xun Sun | Design of a highly stable and uniform thermal test facility for MGRS development |
| 14 |
Ke-Xun Sun | Characterization of High Efficiency Dielectric Gratings for Formation Flight Interferometry |
| 15 |
Ke-Xun Sun | Differential Optical Shadow Sensing |
| 16 |
Ke-Xun Sun | Improved Grating Angular Sensor for LISA and MGRS Applications |
| 17 |
Dylan Sweeney | Laser Communication and Ranging for LISA |
| 18 |
Yinan Yu | Planned arm-locking experiments with variable Doppler shifts on UFLIS |
| 19 |
Noemi Finetti | Study of Test-Mass Charging Process in the LISA Missions due to Diffuse Gamma-Rays |
LISA PathFinder
| 22 |
Christian Killow | Precision alignment of optical components for LISA Pathfinder and LISA |
| 23 |
Davide Tombolato | First study of force noise with the LISA-Pathfinder G.R.S. with sapphire |
| 24 |
Nico Brandt | Electrostatic Model Revisited: Results and Consequences of the LISA Pathfinder Inertial Sensor Finite-Element Analysis |
| 25 |
Felipe Guzmán Cervantes | LISA test mass optical read out: deep phase modulation scheme |
| 26 |
Domenico Gerardi | LISA Pathfinder interferometer acquisition: design and analysis |
| 27 |
Josep Sanjuán | Magnetic polarization effects of temperature sensors and heaters in LISA Pathfinder |
| 28 |
Diana Shaul | How to use a radiation monitor to reduce LISA noise levels |
| 29 |
Daniel Hollington | Simulating the UV Discharge System for LISA Pathfinder |
| 30 |
Peter Wass | Testing the LTP Data Analysis environment with torsion pendulum data |
| 31 |
Michele Armano | Writing operational procedures for the LISA Technology Package |
| 32 |
Giacomo Ciani | A 4-TestMass torsion pendulum for direct force measurements in preparation for LISA and LISA Pathfinder gravitational reference sensor ground testing |
| 33 |
José Ignacio Mateos Martín | Towards an improved magnetic diagnostic system for LISA |
| 34 |
Aleix Conchillo | Software components in the LTP Data Management Unit |
LISA PathFinder Data Analysis
| 37 |
Michele Armano | SW Acceptance Testing for the LISA Technology Package |
| 38 |
Miquel Nofrarias | Thermal coupling within LTP dynamics control loop: diagnostics and data analysis |
| 39 |
Frank Steier | Coupling of test mass jitter into the longitudinal measurement |
| 40 |
Frank Steier | Processing of interferometric data on board LISA Pathfinder |
| 41 |
Nicola Alex Tateo | Design and development of the LTPDA Infrastructure |
Gravitational Wave sources
| 45 |
Priscilla Cañizares | Simulations of Extreme-Mass-Ratio Inspirals using Pseudospectral Methods |
| 46 |
Guillaume Faye | Third post-Newtonian gravitational wave polarisations from inspiraling compact binaries in quasi-circular orbits |
| 47 |
Satoshi Okuzumi | Possible discovery of nonlinear tail and quasinormal modes in black hole ringdown |
| 48 |
Barry Wardell | Quasilocal Contribution to the Self-Force |
LISA Astrophysics
| 50 |
Pablo Lorén | Gravitational wave radiation from white dwarf close encounters in globular clusters |
| 51 |
Alberto Sesana | LISA and Pulsar Timing Arrays: orthogonal tools to constrain Massive Black Hole cosmic history |
| 52 |
Alberto Sesana | Observing white dwarfs orbiting massive black holes in the gravitational wave and electro-magnetic window |
| 53 |
Vicky Kalogera | Probing white dwarf interiors with LISA |
| 54 |
Pau Amaro | Why eccentricity could play a role in IMBHs binaries |
Cosmology and Fundamental Physics with LISA
| 56 |
Odylio D. Aguiar | Perspectives to Testing Quantum Gravity Theories with LISA |
| 57 |
Ernst-Jan Buis | Simulation of the cosmological stochastic background in LISA |
| 58 |
Zsolt Frei | Black Holes in High-Redshift Dark Matter Halos: The LISA Perspective |
| 59 |
Joachim Naef | On the Effect of a Nonvanishing Cosmological Constant on Gravitational Waves |
| 60 |
Wei-Tou Ni | Sensitivities to Scalar Gravitational Waves for LISA, ASTROD |
| 61 |
Larry Price | Stochastic Background of Gravitational Waves from Cosmological Sources |
| 62 |
Fabio Scardigli | Glimpses on the micro black hole Planck phase |
LISA Data Analysis
| 65 |
Gopakumar Achamveedu | The TaylorEt approximant and its implications for LISA |
| 66 |
Arkadiusz Blaut | Grids for effcient all sky search of white dwarf binaries |
| 67 |
Jeff Crowder | A Four-Stage Search for Massive-Black-Hole Binaries in Mock LISA Data |
| 68 |
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| 69 |
Shane Larson | Harmonic correlation for eccentric binaries in gravitational wave observations |
Other Gravitational Wave detectors
| 72 |
Domenico Gerardi | Estimation of the motion of a spherical proof mass with applications to future space-based detectors |
| 73 |
Cesar Lenzi | Determining the neutron star structure using narrow-band gravitational wave detector |
| 74 |
Jun Luo | TEPO project with similar technologies used in LISA Pathfinder |
| 75 |
Antonio Pulido Patón | Gravitational disturbances in drag-free sensors |
