Space Science and the Engines of Change� : Space Science and the Engines of Change Keith Mason
CEO
UK Science & Technology Facilities Council
Astronomy as a change engine : Astronomy as a change engine Human kind is instinctively curious about the world and their place in it
Astronomy, the oldest science, is accessible to all
Discoveries change people’s perceptions of their place in the Universe and their relationship to each other
Generally a ‘non-threatening’ science
Astronomy as ‘entertainment’!
Astronomy Inspires!
People who are inspired can achieve things otherwise beyond them!
Drives technological capability
Wider benefit to society
Drivers not dissimilar to ‘exploration’!
Way forward : Way forward Best way to look forward is to extrapolate from the past
So how far have we come in the last 50 years?
What are the plans for the immediate future?
Where might that lead?
Astronomy in 1957 : Astronomy in 1957 Confined to ‘visible’ wavelengths and radio
Largest telescope 200in (5m) at Mt Palomar
Photographic plates rule!
Radio astronomy in its infancy – 250 ft fully-steerable Lovell telescope just completed
Debate between ‘big bang’ and ‘steady state’ cosmology
Origin of lunar craters – volcanic or impact?
Speculation about life on Mars, oceans on Venus
Take care with ‘experts’ : Take care with ‘experts’ “Space Travel is bunk”
Sir Harold Spencer Jones, British Astronomer Royal, 1957,
2 weeks before launch of Sputnik 1 Lesson: History has a way of overturning even the most
cherished paradigms!
1957-2007: some highlights : 1957-2007: some highlights Travel to the Moon and initial exploration of major planets, comets, asteroids
Understanding the Sun and its effect on the Earth’s environment
Detection of extra-solar planets
Discovery of super compact stars
importance of gravitational accretion as a source of energy
Discovery of quasars
prodigious energy understood as due to accretion onto supermassive black hole at the centre of galaxies
Seeing the birth of black holes
Mapping evolutionary history of stars & galaxies
Cosmic microwave background ‘Big Bang’ cosmology
Measuring the geometry of the Universe
Discovery of ‘Dark Energy’
Slide7 : 1960 1970 1980 1990 2000
Astronomy 2007 : Astronomy 2007 Discoveries in past 50 years fuelled by
access to space,
development of electronics and detector systems,
computers.
Subject transformed compared to 1957
No let up in the pace of discovery
Even if rate of discovery lessens, still likely that subject will take many twists and turns before 2057!
So what is to come?
Future plans : Future plans Consider ESA’s space science programme
Organised in decadal plans
Horizon 2000, Horizon 2000+, Cosmic Visions 2015-2025
Illustrative - Other nations have similar plans, and many missions likely to be realised by international collaboration to make them affordable
So what are the prospects for the next few years? ESA Science
The Herschel Mission : The Herschel Mission THE MISSION:
ESA’s Herschel Space Observatory has the largest mirror ever built for a space telescope. At 3.5-metres in diameter the mirror will collect long-wavelength radiation from some of the coldest and most distant objects in the Universe. In addition, Herschel will be the only space observatory to cover a spectral range from the far infrared to sub-millimetre. Located at L2 (lagrangian point).
OBJECTIVES:
Study the formation of galaxies in the early universe and their subsequent evolution
Investigate the creation of stars and their interaction with the interstellar medium
Observe the chemical composition of the atmospheres and surfaces of comets, planets and satellites
Examine the molecular chemistry of the universe
2008
James Webb Space Telescope�(NASA, ESA, Canadian Space Agency) : James Webb Space Telescope (NASA, ESA, Canadian Space Agency) Infrared optimised successor to Hubble Space Telescope
Mirror diameter 6.5m. Will be located at L2 (operating temperature < 50K)
Themes:
The End of the Dark Ages: First light and re-ionisation
Assembly of Galaxies
Birth of stars & protoplanetary systems
Planetary Systems & the origin of life
2013
The Planck Mission : The Planck Mission THE MISSION:
Planck will help provide answers to one of the most important set of questions asked in modern science - how did the Universe begin, how did it evolve to the state we observe today, and how will it continue to evolve in the future? Planck's objective is to analyse, with the highest accuracy ever achieved, the remnants of the radiation that filled the Universe immediately after the Big Bang, which we observe today as the Cosmic Microwave Background.
OBJECTIVES:
Mapping of Cosmic Microwave Background anisotropies with improved sensitivity and angular resolution
Determination of Hubble constant
Testing inflationary models of the early universe
Measuring amplitude of structures in Cosmic Microwave Background
2008
GAIA: Galactic Archaeology : GAIA: Galactic Archaeology Apparent shift of star position wrt background viewed from opposite sides of Earth’s orbit
Parallax
Measure of distance
GAIA precision 20arcsec
Measure distances at Galactic centre to 20%
~1 billion stars!
Also measure velocity in 3D
Brightness, luminosity and chemical composition
Create a 3-D structural map of the Galaxy!
Earth Orbit about Sun 2011
GAIA Objectives : GAIA Objectives Trace formation history of Milky Way through galaxy mergers
Find planets around stars out to 50 pc (10,000-50,000 planets)
Search for brown dwarf stars
Detect 10,000+ asteroids (including NEOs), comets etc in Solar System
Detect 105 supernovae in distant galaxies
Discover 5 x 105 quasars
Test General Relativity
Gravitational Wave Astronomy : Gravitational Wave Astronomy General relativity predicts that gravitational waves propagate at the speed of light
Ripples from distant binary stars should be detectable as minute distortions in the separations of two appropriately spaced test masses
New field of astronomy!
The LISA Mission : The LISA Mission THE MISSION:
LISA is an ESA-NASA mission involving three spacecraft flying approximately 5 million kilometres apart in an equilateral triangle formation. Together, they act as a Michelson interferometer to measure the distortion of space caused by passing gravitational waves. Lasers in each spacecraft will be used to measure minute changes in the separation distances of free-floating masses within each spacecraft.
OBJECTIVES:
To be the first spacecraft to detect gravitational waves
Measure the properties of binary star systems in the Galaxy and beyond
Test General Relativity under extreme conditions
Search for gravitational signature of the Big Bang
2017
LISA Concept : LISA Concept LISA will consist of three spacecraft arranged in a triangle with sides 5m km
Separation will be measured by interferometry of laser beams shining between the three spacecraft
Change in separation due to gravitational waves tiny – typically 10-10 m from a Galactic binary
Reference point (test mass) must be shielded from external buffeting by, for example, the solar wind
The LISA Pathfinder Mission : The LISA Pathfinder Mission THE MISSION:
LISA Pathfinder will pave the way for the LISA mission by testing in flight the very concept of the gravitational wave detection: it will put two test masses in a near-perfect gravitational free-fall and control and measure their motion with unprecedented accuracy. This is achieved through state-of-the-art technology comprising the inertial sensors, the laser metrology system, the drag-free control system and an ultra-precise micro-propulsion system.
OBJECTIVES:
LISA Pathfinder is to demonstrate the key technologies to be used in the future LISA mission. 2009
Solar Storms : Images from the X-ray Telescope on the Japan/UK/US Hinode satellite (launch Nov 2006) show turbulent solar atmosphere
Coronal mass ejections can result in dangerous radiation levels for humans and instrumentation
Particularly if outside the protection of the Earth’s magnetic field (e.g. Moon)
Solar Storms
Solar Orbiter Sentinels : Solar Orbiter Sentinels Need to understand and predict these outbursts, and how they propagate out from the Sun
Require data from much closer to the Sun
Combination of ESA Solar Orbiter and NASA Sentinels to probe to 0.2 AU (i.e. inside the orbit of Mercury)
Very hostile environment! 2015
The BepiColombo Mission : The BepiColombo Mission THE MISSION:
BepiColombo will set off in 2013 on a journey lasting approximately 6 years. When it arrives at Mercury in August 2019, it will endure temperatures as high as 350 °C and gather data during its 1 year nominal mission from September 2019 until September 2020, with a possible 1-year extension to September 2021.
OBJECTIVES:
- Origin and evolution of a planet close to the parent star
Mercury as a planet: form, interior, structure, geology, composition and craters
Mercury's vestigial atmosphere (exosphere): composition and dynamics
Mercury's magnetized envelope (magnetosphere): structure and dynamics
Origin of Mercury's magnetic field
Test of Einstein's theory of general relativity
2013
The EXOMARS Mission : The EXOMARS Mission First mission in Aurora programme
Launch in 2013
To explore Mars in three dimensions to understand habitability, life potential and hazards to future exploration
High mobility
Drill for sub-surface sampling to 2m depth
Suite of Exobiology instruments
2013
Distant Travellers : Distant Travellers Rosetta (ESA)
Launch 2004
Encounter with Comet 67 P/Churyumov- Gerasimenko 2014
New Horizons (NASA)
Launch 2006
Encounter with Pluto/Charon 2015 New Horizons Rosetta Io/Europa
New Horizons Rosetta Mars Encounter
So what about the future? : So what about the future? 50 years is a long time in the current rapidly developing field of space science/astronomy
Progress and direction will certainly be hijacked by ‘unknown unknowns’!
As it should be since that’s what makes it exciting!!
However many existing/planned missions and facilities have a longevity measured in decades
So interesting to look at people’s current aspirations as a guide to what might be done in the next decades
Aspirations for the Future�(some ideas for ESA Cosmic Visions) : Aspirations for the Future (some ideas for ESA Cosmic Visions) Early Universe & Evolution
2nd generation gravitational wave observatory focussed on residual radiation from the big bang – Universe at <1s
High precision measurements of cosmic microwave background polarisation to test big bang models, inflation
Large area, high spectral resolution X-ray observatory for studying earliest black holes and role in galaxy formation
Dark Energy
High sensitivity surveys for distant supernovae, gravitational lensing – distinguish Dark Energy models
Planetary and Stellar Evolution
Infrared Interferometer: high-resolution spectroscopy at 0.01arcsec spatial resolution, capable of resolving nearby protoplanetary disks.
Survey of 100,000 stars for Earth-like and smaller planets, plus stellar evolution studies.
Environments of Earth-like planets
Molecular hydrogen explorer
High-Energy Universe
First large-area focussing -ray telescope: Gamma-ray bursts, supernovae, AGN, accretion disks, Galactic centre
Aspirations for the Future (cont) : Aspirations for the Future (cont) Fundamental Physics
Accurate measurement of G and limits on change, equivalence principle, link General Relativity and Quantum Mechanics, search for evidence of superstrings
Magnetic Reconnection & Solar Activity
Measure processes in Earth’s magnetosphere with fleet of 12 spacecraft at proton to electron interaction scales.
Sample Solar wind environment very close to Sun Planetary Exploration
Lunar exploration & characterise interior and cosmochemistry, sample return.
Mars networks and sample return
Venus Entry Probe: long-term balloon-bourne investigation plus surface samples
Europa Exploration: characterise ice thickness and surface/interior characteristics leading to search for life in liquid subsurface oceans
Asteroid sample return: 50-100g from surface/subsurface regolith of primitive body.
Example: Extra-Solar Planets : Example: Extra-Solar Planets Over 200 planets known around other stars
Most discovered by dynamical studies
Wobble in parent caused by unseen companion
Favours massive planets close to star (hot Jupiters)
Can also be detected when they transit in front of parent star
Need high sensitivity to detect tiny reduction in stellar light
French-led CoRoT mission launched in 2006
NASA Kepler 2008
Capable of detecting earth-like rocky planets in habitable zone
Search for Life-bearing planets : Search for Life-bearing planets Ultimate aim is to determine whether Earth-like planets harbour conditions for life
Aim of Darwin/Terrestrial Planet Finder missions
Array of spacecraft working together as one
Use Nulling interferometer or coronograph to block out light from parent star
Determine composition of planet’s atmosphere
Possible Headlines from 2007-2057 : Possible Headlines from 2007-2057 Scientists find birthplace of the first stars
Water found in Young Planetary System
Antimatter explorer prepares for launch
Astronomers find missing matter!
Astronomers find every galaxy in the Universe
Astronomers seek the first black holes
Scientists see the beginning of time
Einstein was wrong!
The road to unification finally revealed!
Spacecraft flies into the eye of a Solar hurricane
We are not alone!
When life began!
Doomed worlds
Scientists find biological activity on another Earth!
Earth’s evil twin shows us a glimpse of our future
Life, but not as we know it!
What do we need for a healthy future? : What do we need for a healthy future? Smaller, Faster, Cheaper used to be the
watchwords Smarter With change, still makes sense, so long
as we also use Faster in the sense of
‘higher velocity’
Need to maintain momentum : Tendency for greater challenges to drive more complex missions
Greater cost, more extended timescales, less risk
Harder to inspire when time between and idea and fruition measured in decades!
Mitigation: reduce cost of access to space
Encourage turnover, accept higher risk, encourage innovative solutions
Positive developments:
Investment in infrastructure, for exploration
Commercial launch companies driven by private investors
Innovation & Low-cost platforms (e.g. SSTL)
Need to maintain momentum
Faster travel : Faster travel Current travel time to outer planets, and even Mercury, limits progress
Voyager 1 currently at 100 AU after 30+ years
~0.5 lt days
Need more efficient propulsion to effectively explore outer planets, Kuiper belt and even interstellar space
E.g. ion drive as used recently on SMART-1
More data : More data Increasingly accustomed to a high data-rate environment in science
We have smart, capable instruments that can tackle complex problems
But, ability to get data back from instruments in remote locations an increasing limitation
E.g. Solar Orbiter, where telemetry rate does not permit continuous use of high speed measurements
Need high bandwidth communications infrastructure for entire solar system
E.g. laser comms
Astronomy Access/Protection : Astronomy Access/Protection Favoured sites
L2: deep space, cryogenic
L1: solar
Lunar far side: future large infrastructure
Need to protect environment from the outset
Particularly crucial in radio regime
Mobile phone in the Moon would be one of the brightest astronomical sources seen from Earth!
More robust & available transportation infrastructure
Maintenance & repair at L1, L2 from Lunar space ?
Need efficient transport Solar Deep Space Large infrastructure
End : End