|
⇤ ← Revision 1 as of 2024-12-10 16:41:00
Size: 11863
Comment:
|
Size: 8415
Comment:
|
| Deletions are marked like this. | Additions are marked like this. |
| Line 6: | Line 6: |
| === The 120th REM: Jan 11th, 2024, Thursday === | === The 127th REM: Dec 10th, 2024 === |
| Line 10: | Line 10: |
| * Speaker: M. Tamaki (ICRR) * Title: ''"Suspension Control in KAGRA''" |
* Speaker: Kazuhiro Agatsuma (EX-Fusion Inc) * Title: ''"A career path from gazing star to making star"'' |
| Line 14: | Line 14: |
| Abstract: Ground-based GW detector uses multi-stage pendulum to suspend the mirror for high vibration isolation ratio. However, control noise of suspension limits the low-frequency sensitivity in KAGRA, though low-frequency region has many strong scientific case. This talk will summarize the suspension control in KAGRA and strategies for suspension control noise reduction. }}} * Speaker: M.Yamamoto (Toyama University) * Title: ''"Study of Parametric Instability in KAGRA''" * Abstract: {{{ Abstract: To obtain high shot noise sensitivity, the gravitational wave detectors need to store high laser power in the arm cavity. However, This high laser power causes a phenomenon called Parametric Instability(PI). PI transfers energy from the fundamental optical mode in the arm cavity to the mechanical modes of the mirror. PI has the potential to be an obstacle to higher sensitivity in the future for KAGRA. I will talk about outline of PI and the current status of PI study in KAGRA. |
I show my career path from the field of gravitational waves (GWs) to the field of laser inertial fusion energy (IFE). I have worked on several projects in the GW community for 16 years, for example, TAMA300, CLIO, KAGRA, Ad-Virgo, and Ad-LIGO. The study subjects were broad; seismic attenuation system, pendulum thermal noise, radiation pressure noise, phase camera, and the expansion of the universe. The pandemic caused serious damage in my career, but gave me a chance to challenge another field (IFE). In addition, I show my recent work in EX-Fusion Inc. that is a startup company in Japan. Our goal is to realize a commercial laser fusion reactor. In the future reactor a highly repetitive operation is essential to generate sufficient energy. The fuel targets must be illuminated by the laser spot continuously. However, the target injection system has a limited precision, which causes the target trajectories to fluctuate. The fusion rate can be degraded by a mismatch at the engagement point. We have demonstrated a laser target tracking system to solve this issue. A continuous illumination of targets by 10-Hz operation has been achieved by a controlled mirror. Recently, we have upgraded this system by a new steering mirror, which has a local control system with techniques of GW detectors. |
| Line 26: | Line 19: |
| === The 119th REM: Dec 7th, 2023, Thursday (KAGRA FWG(Future Working Group) + GWREM joint session) === | === The 126th REM: Oct. 31st, 2024 === |
| Line 29: | Line 22: |
| * Time: 9:30-10:10 * Speaker: Marco Meyer-Conde (Osaka Metropolitan University) * Title: ''"Modern machine learning technics and tools in collaboration with CERN"'' |
* Time: 11:00-12:00 * Speaker: Kazuya Kobayashi (ICRR) * Title: ''"Parameter Estimation from Gravitational-wave Data Generated by Compact Binary Coalescences"'' |
| Line 34: | Line 27: |
| Abstract: Timely detection of stellar binary mergers is of the highest interest in both astrophysics and nuclear physics. The use of machine learning technics and mature software with the support of an international laboratory (CERN) and its computer science division will enhance the possibilities and push the boundaries of astrophysics researches. |
Bayesian inference is used to estimate parameters such as masses and spins from gravitational wave data generated by compact binary coalescences. This method allows us to calculate the posterior probability distribution of the parameters. However, since analytical computation in Bayesian inference is difficult, numerical methods such as MCMC sampling are employed. In this talk, I will introduce parameter estimation methods, summarize LIGO-Virgo-KAGRA collaboration results, and present my research on parameter estimation. |
| Line 42: | Line 34: |
| === The 118th REM: Oct 19th, 2023, Thursday === | === The 125th REM: Oct 8th, 2024 === ---- * Time: 14:00-15:00 * Speaker: Satoru Takano (AEI) * Title: ''"Torsion pendulum detector towards gravity gradient detection"'' * Abstract: {{{ Torsion pendulum detector is proposed as a ground-based gravitational wave detector focusing on the 0.1 Hz frequency band [1]. The detector, TOBA (TOrsion-Bar Antenna), consists of two perpendicular torsion pendulums and the small stiffness of the torsion pendulum enables the detector to respond to gravitational waves in low frequencies. The target of TOBA is to observe GWs from IMBH binaries with 10 m bars. To demonstrate the measurement principle and establish necessary techniques, our group has developed small prototypes for more than 10 years. Now we are developing a prototype, Phase-III TOBA. Phase-III TOBA is a big milestone towards the final detector. One of the key features is the cryogenic technique for reduction of thermal noises. Recently, we have demonstrated the cryogenic torsion pendulum cooled down to 6 K[2] and the monolithic readout system made of silicon[3]. I will introduce our TOBA experiment and talk about recent progress. [1] M. Ando et al., PRL, 105, 161101 (2011) [2] T. Shimoda, Ph.D Thesis, The University of Tokyo (2020) [3] S. Takano, Ph.D Thesis, The University of Tokyo (2024) }}} === The 124th REM: September 5th, 2024 === |
| Line 46: | Line 55: |
| * Speaker: Seiji Kawamura (Nagoya University) * Title: ''"Optical-spring quantum locking for DECIGO, juggled interferometer, jiggled interferometer, and displacement-noise-free neutron interferometer"'' |
* Speaker: Hiroki Takeda (Ish Gupta) * Title: ''"Expectations and Challenges on the Path to the Next-Generation of Gravitational-Wave Discovery"'' |
| Line 50: | Line 59: |
| Abstract: At Nagoya University, we are developing various advanced technologies for future gravitational wave detectors, including optical-spring quantum locking for the space gravitational wave antenna DECIGO, a juggled interferometer, a jiggled interferometer, and a displacement-noise-free neutron interferometer. All of these interferometers aim to enhance low-frequency sensitivity beyond the capabilities of standard detection methods. In this presentation, I will elucidate the fundamental principles of these detection methods and provide an overview of their current status. }}} === The 117th REM: Aug 17th, 2023, Thursday === ---- * Time: 17:00-18:00 * Speaker: Keiko Kokeyama (Cardiff University) * Title: ''"History and current shape of the Cardiff group"'' * Abstract: {{{ Abstract: Cardiff University Gravitational Wave Exploration Institute has been playing a leading role in gravitational wave physics. History and current shape of the group will be reviewed. }}} * Speaker: Abhinav Patra (Cardiff University) * Title: ''"Introduction to the QUEST and commissioning updates"'' * Abstract: {{{ Abstract: The QUantum Enhanced Space-Time (QUEST) experiment is currently being commissioned at Cardiff University. QUEST consists of a pair of co-located tabletop power-recycled Michelson interferometers, each targeting a displacement sensitivity of $2 x 10^{-19}$ m/rtHz at 100 MHz. To achieve this sensitivity, the interferometers utilize high circulating power (10 kW) and squeezing. The main science goal of QUEST is to be sensitive to sub-shot noise stochastic signals. These stochastic signals can be a result of spacetime fluctuations due to quantum gravity, interactions of dark matter with the interferometer optics or ultra-high frequency stochastic gravitational waves. }}} * Speaker: Terri Pearce (Cardiff University) * Title: ''"The Polarisation Phase Camera"'' * Abstract: {{{ Abstract: The Polarisation Phase Camera, PPC, is designed to be a non-invasive way of characterising the birefringence of a material. A table top experiment in Cardiff is conducting a proof of principle study of the PPC, with the aim of installing it at the detector sites. I will discuss the motivations, science and status of the experiment. |
The current generation of gravitational-wave detectors have detected close to two hundred binary mergers. These detect ions have imposed constraints on astrophysical populations of binaries, alternate theories of general relativity, cosmological parameters, and the equation of state of the neutron star. Notably, these achievements have been realized despite significant challenges, such as limited localization for most events and the rarity of confidently detected neutron star binaries. Thus, to extract the full potential of gravitational-wave astronomy, bigger and more sensitive detectors are needed. This need will be fulfilled with the Cosmic Explorer and the Einstein Telescope observatories, which are intended to be significantly more sensitive than the current generation. Such observatories will not only increase the number of detections by orders of magnitude, they will also allow for precise estimation of parameters, leading to an era of precision cosmology, refined astrophysical inference and optimized targeted electromagnetic follow-up. In this talk, I will highlight some of these science objectives that will be accomplished by next-generation detectors and address the challenges that must be overcome to realize these objectives, underscoring the importance of concerted efforts in advancing gravitational-wave astronomy. |
| Line 77: | Line 63: |
| === The 116th REM: July 27th, 2023, Thursday === | === The 123rd REM: Jul 30th, 2024 === ---- * Time: 15:00-16:00 * Speaker: Taichi Kawamura (Institut de Physique du Globe de Paris) * Title: ''"Seismic Environment of the Moon"'' * Abstract: {{{ Abstract: More than 50 years after the first landing on the Moon, lunar exploration has once again become a global trend. In the past decade alone, over eight successful lunar landings have been completed, reflecting a growing scientific interest in the Moon. While lunar science remains a primary focus, the potential to utilize the Moon as a natural laboratory for physics and astrophysics is also being explored. Recently proposed experiments include a lunar-based radio astronomy space telescope and a gravitational wave detector. For such projects to be feasible, it is essential to thoroughly understand the Moon's environment, particularly its seismic activity and associated risks. Observations from the Apollo missions have shown that the Moon remains seismically active, experiencing "moonquakes" almost daily. In this presentation, I will review the seismic data obtained from the Apollo experiments and discuss the Moon's seismic environment. I will conclude by highlighting key considerations for future lunar projects. }}} === The 122nd REM: June 27th, 2024 === |
| Line 81: | Line 79: |
| * Speaker: Elenna Capote (Syracuse University) * Title: ''"Advanced LIGO Detector Commissioning for O4"'' |
* Speaker: Prathamesh Joshi (Penn State) * Title: ''"How are gravitational-wave searches for compact binaries performing, and where are they headed?"'' |
| Line 85: | Line 83: |
| Abstract: Both the LIGO Livingston and LIGO Hanford Observatories have made significant progress in upgrading detector sensitivity in preparation for the fourth observing run. This talk will summarize the various equipment upgrades and detector commissioning efforts performed to achieve the new sensitivity. | During the fourth observing run of the LVK collaboration, we have already seen large improvements in the results produced by the CBC search pipelines in low-latency. We have reached new levels of sensitivity and reliability. In the quest to detect every gravitational wave out there, we are now more ready than ever to participate in the next multimessenger event. In this presentation, I will talk about how the searches work, and some recent search results we have seen in O4. As we start getting high-latency offline results, we will begin to explore gravitational waves from new parameter spaces. We are seeing advancements in searches for precessing binaries, higher order modes of gravitational waves, as well as unmodeled or burst searches. I will discuss how these improvements will play a crucial role in obtaining a better scientific understanding of some of the biggest mysteries of the universe. |
| Line 88: | Line 86: |
=== The 115th REM: June 22nd, 2023, Thursday === |
=== The 121th REM: May 30th, 2024 === |
| Line 93: | Line 90: |
| * Speaker: Hiroko Tomoda (Tokyo Univ.) * Title: ''"Optical quantum state generation using waveguide optical parametric amplifiers"'' |
* Speaker: Kenta Tanaka (ICRR) * Title: ''"Introduction to laser interferometric GW telescope and Current status of KAGRA"'' |
| Line 97: | Line 94: |
| Abstract: Optical quantum information processing (QIP) using continuous variables (CVs) of quadrature amplitudes, is a promising approach for large-scale QIP because of its high efficiency of operation and measurement. However, there are many issues left about a quantum light source for CV QIP such as its programmability and broadbandness. Hence we now develop a new light source that can programmably output various optical quantum states required for CV QIP, using broadband squeezers of waveguide optical parametric amplifiers (OPAs). Conventionally waveguide OPAs cannot be used for optical quantum state generation due to their large loss. However, low-loss broadband OPAs have been recently developed [APL Photon. 5, 036104 (2020)] and have become essential devices in our experiments. In this talk, I will introduce our experimental setup and results of time-varying output squeezing level using the OPA [Opt. Express 31, 2161 (2023)]. In addition, I will show our research progress in generating single-photon states and Schrӧdinger’s cat states. | Gravitational wave astronomy has made remarkable progress since its first detection in 2015. The Japanese gravitational wave telescope, KAGRA, is currently undergoing an upgrade to participate in the 4th International Joint Observations with LIGO (USA) and Virgo (Europe). In this talk, I will introduce gravitational waves and the telescopes used for their detection, and provide an update on the current status of KAGRA for new students. |
| Line 99: | Line 96: |
=== The 114th REM: June 1st, 2023, Thursday === ---- * Time: 11:00-12:00 * Speaker: Hiroki Takeda (Kyoto Univ.) * Title: ''"Probing scalar polarizations in gravitational waves"'' * Abstract: {{{ Scalar polarization modes of gravitational waves, which are often predicted in the context of the viable extension of gravity, have been actively searched. However, couplings of the scalar modes to the matter are strongly constrained by the fifth-force experiments. Thus, the amplitude of scalar modes in the observed gravitational-wave signal is expected to be significantly suppressed compared to that of the tensor modes. In this talk, we will discuss the implications of the experiments in the solar system on the detectability of scalar modes in gravitational waves from compact binary coalescences. We first claim that the energy carried by the scalar modes at the generation is, at most, that of the tensor modes from the observed phase evolution of the inspiral gravitational waves. Next, we formulate general gravitational-wave propagation with full polarizations and point out that the energy flux hardly changes through propagation as long as the background changes slowly compared to the wavelength of the propagating waves. Finally, we show that the possible magnitude of scalar polarization modes, which can be probed by the ground-based gravitational-wave telescopes, is already severely constrained by the existing gravity tests in the solar system. }}} === The 113rd REM: April 27th, 2023, Thursday === ---- * Time: 11:00-12:00 * Speaker: Chihiro Hirose (Niigata Unv.) * Title: ''"Alignment Sensing and Control in KAGRA"'' * Abstract: {{{ In international joint observation of gravitational waves, it is necessary to increase the simultaneous operation rate of gravitational wave telescopes to measure the direction of arrival of gravitational waves. In Japan's KAGRA, the mirror is suspended by a pendulum for vibration isolation, but the tilt of the mirror causes drift. To stabilize the optical axis, Alignment Sensing and Control (ASC) needs to be introduced. Wavefront sensing is effective in detecting the difference between the resonator axis and the incident optical axis. Also, KAGRA's mirrors are cooled down to 20 K to reduce thermal noise. Therefore, the mirrors are made of sapphire, which has low mechanical loss even at low temperatures. I investigated the effect of birefringence on ASC by measuring Y-arm error signal. I also actually introduced ASC to the arm. In this gravitational exchange meeting I will talk about the effect of birefringence on ASC, and also about ASC for Observation 4 now. }}} === The 112nd REM: Febrary 28th, 2023, Tuseday === ---- * Time: 17:00-18:00 * Speaker: Kohei Yamamoto (AEI) * Title: ''"LISA metrology system: Clocks, ranging, and communication"'' * Abstract: {{{ The Laser Interferometer Space Antenna (LISA) aims to observe gravitational waves in the mHz regime over its 10-year mission time. LISA will operate laser interferometers between three spacecraft. Each spacecraft will utilize independent clocks, which determine the sampling times of onboard devices called phasemeter to extract the interferometric phases and, ultimately, gravitational wave signals. To suppress limiting laser frequency noise due to time-varying unequal arm lengths, phase signals sampled by each phasemeter must be combined in postprocessing to synthesize virtual equal-arm interferometers with the technique called time-delay interferometry (TDI). The synthesis, in turn, requires a synchronization of the independent clocks in postprocessing. For such on-ground data analysis, additional onboard measurements will be introduced on top of primary phase extractions: intersatellite clock-tone transfer and absolute ranging. The ranging technique also enables intersatellite data communication to ease communication between a ground station and LISA. This talk introduces recent experimental studies of these technologies using a hexagonal optical testbed at AEI Hannover. }}} === The 111th REM: January 26th, 2023, Thursday === ---- * Time: 11:00-12:00 * Speaker: Hiroki Fujimoto (UTokyo) * Title: ''"Axion dark matter search with laser interferometry"'' * Abstract: {{{ Researches on cosmology and astrophysics have revealed that more than 80% of the matter in the universe consists of an unknown substance, or dark matter. The nature of dark matter is still unknown and many searches have been conducted for various dark matter candidates. Axion-like particles (ALPs) are undiscovered particles that are well-motivated candidates for ultralight dark matter. The interaction between ALPs and photons slightly causes the rotational oscillation of linearly polarized light, and therefore ALP dark matter can be detected by the measurement of the polarization rotation of a laser beam. Recently, some ALP dark matter search experiments using the laser interferometer have been proposed. The basic idea is to use an optical cavity, which can enhance the effective light path and also the duration of the interaction with the ALP dark matter. With this technique, the polarization rotation can be amplified and high-sensitive ALP dark matter search can be conducted. In this talk, I will introduce our interferometric ALP dark matter search experiment: DANCE and the search using the gravitational wave detectors. }}} |
The 121-130th REM talks
The 127th REM: Dec 10th, 2024
- Time: 11:00-12:00
- Speaker: Kazuhiro Agatsuma (EX-Fusion Inc)
Title: "A career path from gazing star to making star"
- Abstract:
I show my career path from the field of gravitational waves (GWs) to the field of laser inertial fusion energy (IFE). I have worked on several projects in the GW community for 16 years, for example, TAMA300, CLIO, KAGRA, Ad-Virgo, and Ad-LIGO. The study subjects were broad; seismic attenuation system, pendulum thermal noise, radiation pressure noise, phase camera, and the expansion of the universe. The pandemic caused serious damage in my career, but gave me a chance to challenge another field (IFE). In addition, I show my recent work in EX-Fusion Inc. that is a startup company in Japan. Our goal is to realize a commercial laser fusion reactor. In the future reactor a highly repetitive operation is essential to generate sufficient energy. The fuel targets must be illuminated by the laser spot continuously. However, the target injection system has a limited precision, which causes the target trajectories to fluctuate. The fusion rate can be degraded by a mismatch at the engagement point. We have demonstrated a laser target tracking system to solve this issue. A continuous illumination of targets by 10-Hz operation has been achieved by a controlled mirror. Recently, we have upgraded this system by a new steering mirror, which has a local control system with techniques of GW detectors.
- Abstract:
The 126th REM: Oct. 31st, 2024
- Time: 11:00-12:00
- Speaker: Kazuya Kobayashi (ICRR)
Title: "Parameter Estimation from Gravitational-wave Data Generated by Compact Binary Coalescences"
- Abstract:
Bayesian inference is used to estimate parameters such as masses and spins from gravitational wave data generated by compact binary coalescences. This method allows us to calculate the posterior probability distribution of the parameters. However, since analytical computation in Bayesian inference is difficult, numerical methods such as MCMC sampling are employed. In this talk, I will introduce parameter estimation methods, summarize LIGO-Virgo-KAGRA collaboration results, and present my research on parameter estimation.
- Abstract:
The 125th REM: Oct 8th, 2024
- Time: 14:00-15:00
- Speaker: Satoru Takano (AEI)
Title: "Torsion pendulum detector towards gravity gradient detection"
- Abstract:
Torsion pendulum detector is proposed as a ground-based gravitational wave detector focusing on the 0.1 Hz frequency band [1]. The detector, TOBA (TOrsion-Bar Antenna), consists of two perpendicular torsion pendulums and the small stiffness of the torsion pendulum enables the detector to respond to gravitational waves in low frequencies. The target of TOBA is to observe GWs from IMBH binaries with 10 m bars. To demonstrate the measurement principle and establish necessary techniques, our group has developed small prototypes for more than 10 years. Now we are developing a prototype, Phase-III TOBA. Phase-III TOBA is a big milestone towards the final detector. One of the key features is the cryogenic technique for reduction of thermal noises. Recently, we have demonstrated the cryogenic torsion pendulum cooled down to 6 K[2] and the monolithic readout system made of silicon[3]. I will introduce our TOBA experiment and talk about recent progress. [1] M. Ando et al., PRL, 105, 161101 (2011) [2] T. Shimoda, Ph.D Thesis, The University of Tokyo (2020) [3] S. Takano, Ph.D Thesis, The University of Tokyo (2024)
- Abstract:
The 124th REM: September 5th, 2024
- Time: 11:00-12:00
- Speaker: Hiroki Takeda (Ish Gupta)
Title: "Expectations and Challenges on the Path to the Next-Generation of Gravitational-Wave Discovery"
- Abstract:
The current generation of gravitational-wave detectors have detected close to two hundred binary mergers. These detect ions have imposed constraints on astrophysical populations of binaries, alternate theories of general relativity, cosmological parameters, and the equation of state of the neutron star. Notably, these achievements have been realized despite significant challenges, such as limited localization for most events and the rarity of confidently detected neutron star binaries. Thus, to extract the full potential of gravitational-wave astronomy, bigger and more sensitive detectors are needed. This need will be fulfilled with the Cosmic Explorer and the Einstein Telescope observatories, which are intended to be significantly more sensitive than the current generation. Such observatories will not only increase the number of detections by orders of magnitude, they will also allow for precise estimation of parameters, leading to an era of precision cosmology, refined astrophysical inference and optimized targeted electromagnetic follow-up. In this talk, I will highlight some of these science objectives that will be accomplished by next-generation detectors and address the challenges that must be overcome to realize these objectives, underscoring the importance of concerted efforts in advancing gravitational-wave astronomy.
- Abstract:
The 123rd REM: Jul 30th, 2024
- Time: 15:00-16:00
- Speaker: Taichi Kawamura (Institut de Physique du Globe de Paris)
Title: "Seismic Environment of the Moon"
- Abstract:
Abstract: More than 50 years after the first landing on the Moon, lunar exploration has once again become a global trend. In the past decade alone, over eight successful lunar landings have been completed, reflecting a growing scientific interest in the Moon. While lunar science remains a primary focus, the potential to utilize the Moon as a natural laboratory for physics and astrophysics is also being explored. Recently proposed experiments include a lunar-based radio astronomy space telescope and a gravitational wave detector. For such projects to be feasible, it is essential to thoroughly understand the Moon's environment, particularly its seismic activity and associated risks. Observations from the Apollo missions have shown that the Moon remains seismically active, experiencing "moonquakes" almost daily. In this presentation, I will review the seismic data obtained from the Apollo experiments and discuss the Moon's seismic environment. I will conclude by highlighting key considerations for future lunar projects.
- Abstract:
The 122nd REM: June 27th, 2024
- Time: 11:00-12:00
- Speaker: Prathamesh Joshi (Penn State)
Title: "How are gravitational-wave searches for compact binaries performing, and where are they headed?"
- Abstract:
During the fourth observing run of the LVK collaboration, we have already seen large improvements in the results produced by the CBC search pipelines in low-latency. We have reached new levels of sensitivity and reliability. In the quest to detect every gravitational wave out there, we are now more ready than ever to participate in the next multimessenger event. In this presentation, I will talk about how the searches work, and some recent search results we have seen in O4. As we start getting high-latency offline results, we will begin to explore gravitational waves from new parameter spaces. We are seeing advancements in searches for precessing binaries, higher order modes of gravitational waves, as well as unmodeled or burst searches. I will discuss how these improvements will play a crucial role in obtaining a better scientific understanding of some of the biggest mysteries of the universe.
- Abstract:
The 121th REM: May 30th, 2024
- Time: 11:00-12:00
- Speaker: Kenta Tanaka (ICRR)
Title: "Introduction to laser interferometric GW telescope and Current status of KAGRA"
- Abstract:
Gravitational wave astronomy has made remarkable progress since its first detection in 2015. The Japanese gravitational wave telescope, KAGRA, is currently undergoing an upgrade to participate in the 4th International Joint Observations with LIGO (USA) and Virgo (Europe). In this talk, I will introduce gravitational waves and the telescopes used for their detection, and provide an update on the current status of KAGRA for new students.
- Abstract: