The Goldilocks Zone. It is a phrase that - at least in my own research on the internet - seems to be credited to British astronomer James Lovelock. We live in the Goldlilocks Zone, because, like the porridge in the story of Goldilocks and the Three Bears, our planet's conditions are "not too hot, not too cold, but just right." So many things have come together for our planet to be hospitable for the development - and the flourishing - of life. Dr. Michio Kaku, our favourite theoretical physicist in the entire world, wrote a book called "Parallel Worlds" which discusses this phenomenon. Dr. Kaku will help me explain what we mean when we say we live in the Goldilocks Zone.
Milky Way may be full of meat Scientists have their sights aimed on planets teeming with alien life their telescope sights, that is. In just a decade, astronomers have found over 300 planets orbiting distant stars, and a telescope due for launch in 2013 is expected to find many more.
Tides Have Major Impact on Planet Habitability Astronomers searching for rocky planets that could support life in other solar systems should look outside, as well as within, the so-called "habitable zone," University of Arizona planetary scientists say. Planets too close to their stars are roasted. Planets too far from their stars are frozen. In between, research models show, there's a habitable zone where planet temperatures approximate Earth's. Any rocky planets in this just-right Goldilocks zone could be awash in liquid water, a requisite for life as we know it, theorists say. New research by Brian Jackson, Rory Barnes and Richard Greenberg of UA's Lunar and Planetary Laboratory shows that tides can play a major role in heating terrestrial planets, creating hellish conditions on rocky alien worlds that otherwise might be liveable. And just the other way, tidal heat can also create conditions favourable to life on planets that would otherwise be unliveable.
Intelligent life from other planets would be able to tell that Earth is inhabited if they had come into contact with a space voyaging piece of Orkney rock, scientists have revealed. The specially prepared slab of rock was launched into space attached to a Russian spacecraft by University of Aberdeen experts in September last year as part of a European Space Agency mission.
An international team of researchers has identified a novel place to look for life: on planets that orbit the Sun's stellar siblings. Most of the stars in the Milky Way got their start in clouds of dust and gas that eventually formed clusters of stars. If our Sun started life in such a scenario, the cluster would most likely have drifted apart after a few hundred million of years. But that might have been enough time for life to travel between the rocky debris surrounding each nascent star, according to a study led by astronomer Mauri Valtonen at the Turku University in Finland.
Meteorite experiment deals blow to 'bugs from space' theory A novel experiment has dealt a setback to a theory that life on Earth was kick started by bacteria that hitched a ride on space rocks. The "panspermia" hypothesis is that cells were transported to the infant Earth on rocks that were bumped off other planets or even came from another star system. The theory gained a boost in 1996 when a group of US scientists proposed that a famous meteorite found in Antarctica held traces of fossilised bacteria that once lived on Mars. Seeking to find out more, European scientists have devised "artificial meteorites" to see what happens when rocks bearing fossil traces and living bacteria are exposed to the fiery heat of entering Earth's atmosphere. In research to be unveiled on Wednesday, they attached small rocks two centimetres thick to a Russian unmanned Foton M3 capsule that was launched in September 2007 and returned to Earth 12 days later.
Title: Minimal Energy Transfer of Solid Material Between Planetary Systems Authors: Edward Belbruno, Amaya Moro-Martin, Renu Malhotra (Version v2)
The exchange of meteorites among the terrestrial planets of our Solar System is a well established phenomenon that has triggered discussion of lithopanspermia within the Solar System. Similarly, could solid material be transferred across planetary systems? To address this question, we explore the dynamics of the transfer of small bodies between planetary systems. In particular, we examine a dynamical process that yields very low escape velocities using nearly parabolic trajectories, and the reverse process that allows for low velocity capture. These processes are chaotic and provide a mechanism for minimal energy transfer that yield an increased transfer probability compared to that of previously studied mechanisms that have invoked hyperbolic trajectories. We estimate the transfer probability in a stellar cluster as a function of stellar mass and cluster size. We find that significant amounts of solid material could potentially have been transferred from the early Solar System to our nearest neighbour stars. While this low velocity mechanism improves the odds for interstellar lithopanspermia, the exchange of biologically active materials across stellar systems depends greatly upon the highly uncertain viability of organisms over the timescales for transfer, typically millions of years.
Japan's biggest astronomical observatories are teaming up for an unprecedented quest to find out whether there is life in outer space. The project, led by Japanese astronomers, will bring together a dozen or more observatories from all over the country to study one star that researchers see as a potential home to an extraterrestrial civilization.
The technology needed to send a robotic probe to another solar system is far in the future at best. But one scientist says it's not too soon to start thinking about how to avoid contaminating extrasolar planets with hitchhiking microbes from Earth.