Science Case for LISA Pathfinder Paul McNamara LISA Pathfinder Project Scientist 30 th & 31 st January 2007.

Slides:

Advertisements

Similar presentations

The LISA Technology Package on board of LISA PATHFINDER will enable testing of following LISA key technologies: 'Inertial Sensor': to demonstrate that.

Advertisements

Space Science Project Funding by the German Space Agency (German Aerospace Center, DLR) Werner Klinkmann, DLR Space Agency, Bonn.

Laser Interferometer Gravitational-wave Detectors: Advancing toward a Global Network Stan Whitcomb LIGO/Caltech ICGC, Goa, 18 December 2011 LIGO-G v1.

1 Planetary probes: ESA Perspective Jean-Pierre Lebreton ESA’s Huygens Project Scientist/Mission Manager ESA’s EJSM & TSSM Cosmic Vision Study Scientist.

Hubert HalloinScientific Committee 2013 WP Interface I3(APC/IPGP) : Fundamental Physics and Geophysics in Space Introduction and context  Fundamental.

1 Measurement of the Gravitational Time Delay Using Drag-Free Spacecraft and an Optical Clock Neil Ashby, Dept. of Physics, UCB 390, University of Colorado,

A particle monitor for LISA Pathfinder and Gravity Probe-B gyroscope charging in LEO Peter Wass, Henrique Araújo, Tim Sumner Imperial College London, UK.

System consisting of three stars: Alpha Centauri A, Alpha Centauri B, and Proxima Centauri Alpha Centauri A and B (depicted at left) form a binary star.

Laser Interferometer Space Antenna Satellite Description  Three spacecrafts forming a triangle flying 5 million km apart  Placed in an elliptical plain.

Exploiting the Proton’s Weakness L. Cobus, A. Micherdzinska, J. Pan, P.Wang, and J.W. Martin The Standard Model of Physics New Physics??IntroductionFocal.

“Galileo Galilei” (GG) GG Phase A-2 Study funded by ASI ongoing at TAS-I (TO) with support from GG/GGG scientists GG target: test the Equivalence Principle.

Navigation using pulsars ASTRONOMY AND SPACE SCIENCE George Hobbs Nov 2014.

Paik-1 Exploring Gravity with Proof-Mass Technologies Ho Jung Paik University of Maryland July 6-10, 2008, Warrenton, VA.

LIGO -- Studying the Fabric of the Universe LIGO-GOxxxx Barry C. Barish National Science Board LIGO Livingston, LA 4-Feb-04.

Current progress of developing Inter-satellite laser interferometry for Space Advanced Gravity Measurements Hsien-Chi Yeh School of Physics Huazhong University.

G O D D A R D S P A C E F L I G H T C E N T E R 1 GW Interferometry at Goddard Space Flight Center Jordan Camp NASA / Goddard Space Flight Center Jan.

eLISA (or NGO): the New LISA

Current Progress of Development of Laser Interferometry for LISA-type Mission in China Hsien-Chi Yeh School of Physics Huazhong University of Science &

1 Wei-Tou NI Center for Gravitation and Cosmology Purple Mountain Observatory Chinese Academy of Sciences Nanjing, China On Technologies Common to DECIGO,

1 LISA Science and Concept Robin T. Stebbins. 2 May 13, 2003 LISA Overview The Laser Interferometer Space Antenna (LISA) is a joint ESA- NASA mission.

Williams Research Gravity Pharis E. Williams 19 th Natural Philosophy Alliance Albuquerque, NM July, 2012.

What is Physics?. Physics Defined The dictionary definition of physics is “the study of matter, energy, and the interaction between them”, but what that.

Technology Input Formats and Background Appendix B.

System Design Assessment for a Mission to Explore the Pioneer Anomaly Jonathan Fitt School of Physics and Astronomy, University of Birmingham, Edgbaston,

LISA Update Bernard Schutz Albert Einstein Institute, Potsdam, Germany and Cardiff University, Wales GWDAW-10, Brownsville, 14 December 2005.

Recent determination of Gamma with Cassini M.T. Crosta, F. Mignard CNRS-O.C.A. 5th RRFWG, June, Estec.

Z B Zhou, Y Z Bai, L Liu, D Y Tan, H Yin Center for Gravitational Experiments, School of Physics, Huazhong University of Science.

Inertial Sensor and Its Application for Space Fundamental Experiments Ze-Bing Zhou ( 周泽兵 ), Jun Luo ( 罗俊 ) Center for Gravitational.

LISA Pathfinder A Technology Demonstrator for the LISA Space Gravitational-Wave Detector Gerhard Heinzel and Albrecht Rüdiger, AEI Hannover Third International.

08/31/2006 ~ Mission specific challenges: Data Analysis GRS Interferometry.

International Conference on Topics in Astroparticle and Underground Physics (Sept. 11, 2007, Sendai, Japan ) DECIGO Pathfinder Masaki Ando (Department.

ISAAC NEWTON’S PHYSICS PRINCIPLES. WHAT NEWTON DID When it comes to science, Isaac Newton is most famous for his creation of the THREE LAWS OF MOTION.

Chapter 2 MOTION. - one of the more common intangible concepts in science - is the act or process of changing position TWO IMPORTANT ASPECTS OF MOTION.

Fundamental Principles of General Relativity  general principle: laws of physics must be the same for all observers (accelerated or not)  general covariance:

Laws of Motion Forces: chapter st Law An object at rest remains at rest and an object in motion maintains its velocity unless it experiences an.

Bridging the Gap between Terrestrial Detectors and LISA Elba 2002 May 24, 2002 Seiji Kawamura National Astronomical Observatory of Japan.

1. G O D D A R D S P A C E F L I G H T C E N T E R 2 New Budget Initiatives for NASA in FY04.

SE&I Pre-Proposal Meeting GSFC - JPL Systems Engineering Management Colleen McGraw.

Summary for Chapters 2  4 Kinematics: Average velocity (Instantaneous) velocity  Average acceleration = (Instantaneous) acceleration = Constant acceleration:

DECIGO – Japanese Space Gravitational Wave Detector International Workshop on GPS Meteorology January 17, Tsukuba Center for Institutes Seiji Kawamura*

Astrophysics to be learned from observations of intermediate mass black hole in-spiral events Alberto Vecchio Making Waves with Intermediate Mass Black.

LISA News from ESA O. Jennrich LISA Project Scientist.

Proudly Present WELCOME TO OUR PRESENTATION 3 21 GROUP5GROUP5 G R O U P 5.

Deci-hertz Interferometer Gravitational Wave Observatory (DECIGO) 7th Gravitational Wave Data Analysis Workshop December 17, International Institute.

1-1: What is Physics? Objectives: Identify activities and fields that involve the major areas within physics Describe the process of the scientific method.

Space Gravitational Wave Antenna DECIGO Project 3rd TAMA Symposium February 7, Institute for Cosmic Ray Research, Japan Seiji Kawamura National.

Mike Cruise University of Birmingham Searching for the fifth dimension using gravitational waves.

G O D D A R D S P A C E F L I G H T C E N T E R 1 Status of LISA Jordan Camp LISA Deputy Project Scientist NASA / Goddard Space Flight Center Jan. 19,

Science of Physics What Is Physics?. Topics of Physics Physics is the study of the physical world Why things do what they do Physics is all around us.

Understanding Microcosms Matthew Anstead Logan Barmore Ryan Barton Ilona Harden.

V Galileo: The object would land at the base of the mast. Therefore, an observer on a ship, moving (with respect to land at velocity v) will observe the.

LISA Laser Interferometer Space Antenna: The Mission Mike Cruise For the LISA Team.

The Quest for Gravitational Waves: a global strategy

Physics Unit 0.1.

DECIGO Pathfinder Masaki Ando

GW150914: The first direct detection of gravitational waves

Chapter 12 Section 2 Gravity Objectives

GrAnd Unification and Gravity Explorer

Notes 2- Gravity, Friction, and Newton’s Laws

Newton`s I law (a) state each of Newton’s laws of motion

Toys in Space National Aeronautics and Space Administration

This Week Today: Wednesday Friday: We finish up with Gravity

Electromagnetic Waves

5.2 Properties of Light Our goals for learning What is light?

What is gravity????.

ENERGY Energy J Kinetic Energy J Elastic potential energy J Ek Ee E

Laser Interferometry for a future GRACE follow-on mission

Presentation transcript:

Science Case for LISA Pathfinder Paul McNamara LISA Pathfinder Project Scientist 30 th & 31 st January 2007

LISA Pathfinder SSAC 30 th /31 st January 2007 Why LISA Pathfinder? The science case for LISA is extremely compelling and has continually been highly ranked by independent review boards However, both ESA and NASA believed that the risk was too high to fly LISA with an unproven measurement concept LISA Pathfinder was instigated by ESA to test the concept of low-frequency gravitational wave detection The LPF development has shown that the technologies required for LISA are difficult, but not impossible –LPF has already solved many of the challenges associated with low frequency gravitational wave detection With LISA Pathfinder, ESA paves the way for LISA and future fundamental physics missions

LISA Pathfinder SSAC 30 th /31 st January 2007 Foundations of General Relativity The most basic assumption of General Relativity is that free-particles follow geodesics unless acted upon by an unbalanced force The definition of geodesics in Einstein’s “The Meaning of Relativity” ALL missions aimed at demonstrating an aspect of GR rely on geodesics LISA Pathfinder will be the first mission to demonstrate that free particles do indeed follow geodesics at such an unprecedented level –Requires that the free-particle is measured with respect to another free-particle!

LISA Pathfinder SSAC 30 th /31 st January 2007 Mission Concept

LISA Pathfinder SSAC 30 th /31 st January 2007 Science demonstrated with LPF Geodesic motion of free particles Pico-meter/nano radian laser metrology to free falling mirrors Nano-metre three-body “formation flying” –2 nd TM and spacecraft servoed to follow primary TM (to better than 10pm/  Hz and 2nm/  Hz at 1mHz respectively) Materials physics –Test mass magnetic properties –Patch field effects –Thermal effects Precision modelling of cosmic ray charging –Correlate test mass charge with models and on-board particle detector

LISA Pathfinder SSAC 30 th /31 st January 2007 Goal of LPF To put test mass into (almost) perfect free-fall Spurious accelerations kept to less than Current best “on-orbit” performance by GRACE: LPF will demonstrate ~TWO orders of magnitude better performance than has been, or is currently planned to be (with the exception of LISA), demonstrated on-orbit! –MICROSCOPE should demonstrate ~ ms -2 /  Hz at 1mHz

LISA Pathfinder SSAC 30 th /31 st January 2007 Performance of LPF

LISA Pathfinder SSAC 30 th /31 st January 2007 Comparison of missions

LISA Pathfinder SSAC 30 th /31 st January 2007 LPF Legacy The main output of LPF is the physics model of the free falling test mass and its environment –Model of the electromagnetic and gravitational interactions at play when dealing with extremely small forces and low acceleration levels This physical model will be used to extrapolate to the parameter ranges relevant to a host of other missions –e.g. LISA, Pioneer Anomaly, SSI, etc The models (updated with on-orbit data) are designed to be plugged into the spacecraft/environment simulators of future missions

LISA Pathfinder SSAC 30 th /31 st January 2007 Missions: Fundamental Physics [1] LISA LATOR (Cassini) ASTROD Microscope (FEEPS)

LISA Pathfinder SSAC 30 th /31 st January 2007 Future missions: Fundamental Physics [2] Probable submission to the Cosmic Vision AO (among others in FP): GAUGE Pioneer Anomaly? Fundamental Physics Explorer

LISA Pathfinder SSAC 30 th /31 st January 2007 Missions: Earth Observation GRACE (Launched 17/3/2002) GOCE (Launch 2007) SSI (GRACE/GOCE follow-on mission) –Re-use of LTP inertial sensor AND laser interferometry

LISA Pathfinder SSAC 30 th /31 st January 2007 Conclusions LISA Pathfinder will be the first mission with the specific goal of demonstrating geodesic motion of a free-particle LISA Pathfinder is the first step in the development of low frequency gravitational wave telescopes The science and technology knowledge gained from LISA Pathfinder will be re-used in future missions With the descope of the NASA provided DRS, the LTP is the ONLY inertial sensor planned to be flown, and gives Europe a significant lead in this and related fields. The LISA Pathfinder platform allows future fundamental physics missions to become reality More information on the Science Case for LPF can be found in: LISA Pathfinder: Einstein’s Geodesic Explorer [ESA-SCI(2007)1]

LISA Pathfinder SSAC 30 th /31 st January 2007 LTP on LPF