Extraterrestrial (TV documentary)
|Also known as||
'Alien Worlds |
Extraterrestrial - Alien Worlds'
|Directed by||Nick Stringer|
|Presented by||Armand Leroi (UK)|
Simon Conway Morris |
Armand Leroi (UK) |
Michael Dorn (US)
|Composer(s)||The Fratelli Brothers|
|Country of origin||
United Kingdom |
|No. of series||1|
|No. of episodes||2|
|Executive producer(s)||Sarah Cunliffe|
2 hours with commercials|
100 minutes without commercials
|Production company(s)||Big Wave Productions Ltd.|
Channel 4 (UK) |
National Geographic Channel (US)
January, 2005 (UK) |
May 30, 2005 (US)
|Official website (archived link)|
Extraterrestrial (also Alien Worlds in the UK) is a British-American two-part television documentary miniseries, aired in 2005 in the UK by Channel 4, by the National Geographic Channel (as Extraterrestrial) in the US on Monday, May 30, 2005 and produced by Blue Wave Productions Ltd. The program focuses on the hypothetical and scientifically feasible evolution of alien life on extrasolar planets, providing model examples of two different fictional worlds, one in each of the series's two episodes.
The documentary is based on speculative collaboration of a group of American and British scientists, who were collectively commissioned by National Geographic. For the purposes of the documentary, the team of scientists divides two hypothetical examples of realistic worlds on which extraterrestrial life could evolve: A tidally locked planet orbiting a red dwarf star (dubbed "Aurelia") and a large moon (dubbed "Blue Moon") orbiting a gas giant in a binary star system. The scientific team of the series used a combination of accretion theory, climatology, and xenobiology to imagine the most likely locations for extraterrestrial life and most probable evolutionary path such life would take.
The "Aurelia" and "Blue Moon" concepts seen in the series were also featured in the touring exhibition The Science of Aliens.
Series concept and scientific basis
At the start of the documentary, the presenter and team of scientists draw attention to their reasons for speculating about life on extrasolar planets. Discoveries regarding extrasolar planets were first published in 1989 raising the prospect of whether life (as we know it or imagine it) could be supported on other planets. It is currently believed that for this to happen a planet must orbit in a relatively narrow band around its parent star, where temperatures are suitable for water to exist as a liquid. This region is called the habitable zone.
The sensitivity of current detection methods makes it difficult for scientists to search for terrestrial planets smaller than this. To allow smaller bodies to be detected, NASA was studying a project called the Terrestrial Planet Finder (TPF), a two-telescope concept slated to begin launching around 2014. However, Congressional spending limits under House Resolution 20 passed on January 31, 2007 by the U.S. House of Representatives and February 14 by the U.S. Senate have all but canceled the program.
Prior to the TPF's cancellation, astrophysicists had begun speculating about the best places to point the telescope in order to find Earth-like planets. Whereas life on Earth has formed around a stable yellow dwarf, solar twins are not as common in the galaxy as red dwarf stars (which have a mass of less than one-half that of the Sun and consequently emit less heat), or bigger, brighter blue giants. In addition, it is estimated that more than a quarter of all stars are at least binary systems, with as many as 10% of these systems containing more than two stars (trinary etc.)—unlike our own sun, which has no companion. Therefore, it may be prudent to consider how life might evolve in such environments. Such speculation may still be of use should a future planet-finding telescope be launched, and possibly for NASA's Kepler mission.
Episode 1: Aurelia
The scientists on the project theorized that aiming the TPF at a red dwarf star might yield the best opportunities for seeing smaller planets. Due to the slow rate at which they burn hydrogen, red dwarfs have an enormous estimated lifespan; allowing plenty of time for life to evolve on surrounding planets. Also, red dwarfs are very common in the universe. Therefore, if they support habitable planets, it substantially increases the chances of finding life in the universe. However, being much dimmer than other stars, it will be harder to detect planetary systems around them. In addition, lower gravity would limit the potential size of a system. The discovery of Gliese 581 g raises hopes of finding more red dwarf systems, including potentially habitable ones.
However, the dwarf's smaller nature and fainter heat/light output would mean that such a planet would need to be particularly close to the star's surface. The cost of such an orbit would be that an Earth-sized body would become tidally locked. When this happens, the object presents the same face to its parent at all times as it orbits, just as the Moon does with the Earth (more technically, one sidereal day is exactly equal to one year for the orbiting body).
Traditional scientific theories proposed that such a tidally locked planet might be incapable of holding on to an atmosphere. Having such a slow rotation would weaken the magnetic effect that protects the atmosphere from being blown away by solar wind (see Rare Earth hypothesis).
Traditional assumptions tested
Nonetheless, the scientists employed by the programme decided to test the traditional assumptions for such a planet and start a model out for it from a protoplanetary disk through to its eventual death. Their estimations suggested such a planet could indeed hold on to its atmosphere, although with freakishly unusual results by Earth standards. Aurelia would be gravitationally locked to its star (a red dwarf). Due to this, Aurelia would not have seasons or a day/night cycle, as half of Aurelia would be in perpetual darkness and would be in a permanent ice age. The other half would contain a giant, unending hurricane with permanent torrential rain at the point directly opposite the local star. In between these two zones would be a place suitable for life.
This hurricane could perhaps generate enormous waves in the ocean and the waves would migrate outwards. Oceanographers should test how high these waves would be in the postulated nearby swamps and delta area. They would be wind driven waves and would not reach from the top of an ocean to the bottom like a tsunami. Nonetheless, waves as big and as devastating as those that humans call freak waves might be regular. Simple bacterial and algal life would not be threatened.
Lifeforms of Aurelia
At the far end of assumptions about Aurelia were attempts to construct lifeforms based on Earthly evolutionary models and how ecosystems might develop. The scientists' assumptions included the idea that the long life of a red dwarf allows for evolution to fine-tune any ecosystem on the planet. The scientists involved in the project hypothesized that the vast majority, if not all, of extra-solar biology will be carbon-based.
From this carbon-based hypothesis the scientific team assumed some form of staple photosynthesizing animal/plant combination would be the principal autotroph. They decided upon a plant-like creature called a Stinger Fan. It has five hearts and limited mobility. Its fan-like leaves trap the red dwarf star's energy to produce sugars. Its hearts pump them around its body.
Feeding upon the Stinger Fans are six-legged semi-amphibious beaver like creatures called Mudpods. They use their long, continually growing thumb claws to cut down a Stinger Fan and dam the river systems, creating artificial lagoons and swamps which provide safety from predators. Upon that animal, a large emu-like animal, the Gulphog, is the main predator. These 2 meter tall carnivores live socially in packs, and display promising signs of intelligence. Finally, there is a second semi-amphibious creature called the Hysteria - a cross between a plague of tadpoles and piranha. These tiny, orange creatures can collect together (in a manner similar to slime molds) and form one huge super-organism, moving together up banks to paralyze and consume other animals. Scabian Slugs that live by the water can fall victim to the Hysteria, but it can take something as large as a Gulphog to satisfy them.
The planet's ecosystem suffers from a number of particular peculiarities, most notably evolutionary quirks to allow all living organisms to detect and avoid solar flares. Red dwarf stars are unstable and eject frequent solar flares. Such intense ultraviolet radiation is deadly to all carbon-based life forms as it breaks down the atomic bonds formed by organic compounds. The Gulphogs have adapted by having an ultraviolet light sensitive eye on top of their heads. Stinger Fans fold up to protect themselves. Mudpods have sensitive backs that can sense the ultraviolet rays. The Hysteria's adaption is unknown. However, the flare stage might only be when the red dwarfs are relatively young.
Episode 2: Blue Moon
The Blue Moon is covered in life-giving water and an atmosphere so dense that enormous creatures hypothetically can take flight. The Blue Moon orbits a Water Cloud Jovian planet (a Jupiter-like planet that is cool enough to have visible rain clouds in its atmosphere) orbiting a close binary star system. The Blue Moon itself is roughly an earth mass but has an air pressure around three times that of Earth's at sea level.
A distinguishing feature of Blue Moon is that it has no polar ice caps: the thick atmosphere keeps temperatures constant across the moon's surface. There is also a greenish haze over the moon from large carpets of floating moss and algae.
The denser atmosphere allows more massive creatures to remain airborne than on Earth. Skywhales, gargantuan whale-like animals which evolved away from the ocean into the air, fill the ecological niche this creates. Because of the increased muscle power from excess atmospheric oxygen, these creatures can have wingspans of ten meters and remain airborne their entire lives. They feed on the previously mentioned Air Moss. They evolved from seagoing animals into flying ones in one evolutionary leap.
High levels of oxygen (30% of the atmosphere) push the atmosphere to the brink of spontaneous combustion during lightning storms. Carbon dioxide levels are thirty times higher than on Earth making the air clammy and warm. Like our moon, Blue Moon is tidally locked, meaning it keeps the same side of the moon faced towards its planet.
With an orbital time of roughly ten days, that means five days of continuous night and five days of continuous daytime. The long days and nights also create strong cross-hemisphere winds that help keep the Skywhales afloat, in addition to the density of the atmosphere and its increased oxygen concentration compared to Earth.
Lifeforms of the Blue Moon
Skywhales are prey to the insect-like caped Stalkers, colony-living predators that have several different tasks. Scouts find skywhales and mark them with a special scent, then return to the nest to spread the word. Workers then swarm out in huge numbers, detecting the whale and working together to bring them down from the sky and kill them. Finally, there is a queen, who stays in the nest and constantly lays eggs that become new stalkers. This lifestyle is based on earth's hornets. The Stalkers are also prey, for the Pagoda branches are draped with the lethal webs of the plant-like ghost traps. Once a Stalker is caught in a ghost trap web, the carnivore uses its tentacles to lift its catch up into its mouth, to be digested by the acid in a primitive stomach.
As well as Skywhales, giant Kites also fly above the forest canopy. These parasol-like grazers can grow up to 5 m (16 ft) in diameter and still stay airborne. Their tethers help control their floating, while their jellyfish-like tentacles snatch Helibug larvæ from the water-filled skyponds. Helibugs have a trilaterally symmetrical body plan, with three eyes, three wings, three legs, three mouth parts and three tongues.
70% of Blue Moon's land mass is coated in two main plant types, pagoda trees and balloon plants. Pagoda trees interconnect with each other to allow them to grow 700 ft (210 m) tall. Their hollow leaves collect rainwater, since the trees are too tall to draw it from the ground. Balloon plants release their seeds by filling them with hydrogen to float in the dense atmosphere, in a way similar to kelp on Earth.
The Blue Moon is threatened by mass wildfires that can wipe out entire pagoda forests. Balloon plants grow in the gaps resulting. The floating balloons released by the plants are full of explosive hydrogen, and when a fire hits, they explode like bombs, releasing seeds flying through the air. Skywhales and Kites will gain altitude until the fire ends. The Stalkers' escape strategy is unknown.
Home video releases
- Lovgran, Stefan (3 June 2005). "Flying Whales, Other Aliens Theorized by Scientists". National Geographic News. Retrieved 16 October 2011.
- "TV Review - National Geographic's 'Extraterrestrial'". www.space.com. www.space.com. 27 May 2005. Retrieved 27 October 2016.
- "Sky Whales & Pagoda Forests - Scientists Study Possible Course of Evolution on Planets Beyond Our Solar System". www.dailygalaxy.com. www.dailygalaxy.com. March 2008. Retrieved 27 October 2016.
- "Make Contact with Alien Creatures in National Geographic Channel Special 'Extraterrestrial'". www.prnewswire.com/news-releases/. prnewswire.com. 20 May 2005. Retrieved 27 October 2016.
- Bell, Richard (25 November 2005). "Stinger Fans on Alien Worlds". Richard Bell's Wild West Yorkshire Nature Diary. Archived from the original on 19 May 2007. Retrieved 29 April 2007.
- Cooper, Sean (February 2006). "Alien Animal Planet". Wired. 14 (2). Retrieved 30 March 2012.
- "Extraterrestrial - Alien Worlds [DVD] Amazon.co.uk: DVD and Bluray". Extraterrestrial - Alien Worlds [DVD] Amazon.co.uk: DVD and Bluray. Amazon.co.uk, Channel 4. Retrieved 27 October 2016.
- Extraterrestrial at the Internet Movie Database (US version)
- Alien Worlds at the Internet Movie Database (UK version)
- Extraterrestrial at National Geographic Channel, captured by the Wayback Machine