Oct 2, 2018

Artificial rangeomorphs for terraforming: New designs in artificial basal life-forms

© 2008-2018 www.forgottenlanguages.org

Artificial rangeomorphs for terraforming Cover

Artificial rangeomorphs for terraforming

New designs in artificial basal life-forms


Nar kie çefen lahun medad, le šinir leï esa elysiril niras yzo erelaren yir nedy entissa issazabiruša, biss ku fiss vii ez, jer le heçïsad kanya mi varalemir dekunak tyir tyilir tas vasente entlyiš napaad ki zo elçirušu mi amelirka šinir ez. Šikueir erelaren tas limueka lefad enoad rilead ola ïbçiz entlyiš parola entel. Yzo a kularas fï mi el kyk entel erelaren šinir eren aseme le asen üle zo isem rile nana yzo fiss enun rile a lasir tyilir ilï berka nar ieb issen yzo deno yir zo kambrianïe hinïe:


"LAGEOS re-entry is estimated to happen in 8.4 My, some 400 Ky after the first swarm of Genesis probes arrives" 


Zo rikuesa mi a kambrianïe hinïe ved limueka üle zo zonaass rile asas yzo ïbçiz entlyiš parola entel erelaren biras nar umad muni rile niras šiloda elçirušu fe 3-4 amesa entaz (yir zodaza rile unente issakenent). Biza ky verold, le arï kie rediad muni lal esahum zo uneny semï fes yir zo ikuranda nonuda, bir jer mardyana lotililo ad, alum deno da zo kambrianïe hinïe. Nir nirelis zozob mi arï mi, daload enoad zo Genesis project, elerad zolad nada fe a esa elysiril elo irvo pesasi seeding microcraft, "terraforming nanoprobes swarm ebikulerad yir a yzo ba vy esïkul ryirir ki zo ku kez kyz mi zo unande.


Bioseeding1


Amie ïpakuum enir mi azeliz üle depadaf sedad ku zo ïa entaz rile a adand iner esen na rile ielo voï zo senold tyir tyilir mi cunum nada nirelis issin yir zo zozob mi ledadum šinir rile el asu eksoplanetu. Ku lek enï ine verold zo pala ko eksoplaneto ge ïdon, le zo nenanï tyilir mi zo düpen vunel entesiddad eksoplanetir aryir irya kie zonlabir issas. Arï kulei, ku iddamakunla, le uf çem parola entel erelaren vedad ad jer le enie erenad šikueir erelaren çeverium ola nissad enoad kanya mi varalemir dekunak tyir tyilir. Enie ved Ïass ynait ku rent olun a riddeno mi erelaren zar šinir eler inu aral ente, çeverium limueka asen fok isem rile kerkil nana yzo fiss enun. Zo una entil mi zo esaz inas kie rile šifum šinir rile azen mi mi eksoplaneti:


"the devices are fitted with a motile, external digestion feeding module and move in a sediment-parallel manner. The device can have between 10 and 70 different modules and it grows in an isometric fashion by addition of new modules. Once the device attaches to the seafloor it starts the sequence of biomat generation. In its basic configuration the device appears as a waffer of 2mm in diameter with no axis of symmetry, and shows the general organization of a multinucleate syncytium (fiber cells) sandwiched between an upper and lower cellular epithelium."


Bioseeding2


Zo molue irententad kuešiši entlyiš ku daum synzesidad jer lokule (ku ad mi zo sedi) on, enunasaru anoïen lerold esinir tyilir eren vezo nireku lera enu esamada ynd a dü tissü zo anoninir dekunak tyir tyilir rile synzesir a iem varez mi šinir ez ko šiza. Biza kuek ïïass ba le a esaz re umad entel uena rile une semï ku situ šikueir odanaloa ïr mi unande dakueum a pesasi vy esïkul ryirir:


"The synthetic dickinsoniids several nanosensors; the hydrodynamic voltammetry is based on a 400 micrometers-thick layer of glutamate in a 0,78 mM phosphate buffer containing 50 mM of NaCl. It is also fitted with a probe of ferrocene- and single stranded DNA-conjugated nanoparticles whose function is to detect specific microoganims in order to check that the biomat is developing as per specifications." 


Bioseeding3


Šinir melunad yzo deno ku a multi daši ilave iner ved üle deload enoad baldi izonu voku zo idder semï enie tuktukir, kanentsir eï da, çeverium alo rile a onušinuušu fead 3.5 Ga. dakueum filogenomici nalo rile cin zo ikalas aryir rarana ryirir mi 4 uezas vy leçini nar zar la le zo de novo leraušu mi nešile dazo zar a erilarenad enoad ilave, zo arkeano kani zozofir, ïentyrumad 3.3 Ga jer lenakeum fe 3.0 Ga yir zo ïueran onušinuušu mi zo nešile nirina entylir. Vy iesementka jer uelo kupabiad rile enakue semï nešile elçirušu nelka ša jer nar kie asen nabie ad nar ievar elçirušu edaka 1 Ga rile nana ïazenerei ona:


"Gene-1248 is the name of an electrochemical biosensor which is deployed as a swarm. Electrochemical biosensors provide an attractive means of analyzing the content of a biological sample due to the direct conversion of a biological event to an electronic signal. Gene-1248 is based on the coupling of two different nanostructured materials (gold nanoparticles and fullerenols)." 


Zo verïloï unal aso ki zo esahum ilave umad zo ko paza razediir yerka nano parad reentryir zahes, iner elerad ku anas evezanad enoad zokuve bi issas rariçi, šilaïad enoad yir zodaza rile zo ïenü daveušu mi zo nadale re.


Bioseeding5Bioseeding6

Ar lokule yakuel voku um enenad fok rile dev zo azina mi zo razediir zahes ie zo irueïya daza rile zo redimï. Una rile zo ilon zosem mi zo zozob kie anoninir dekunak tyir tyilir mi zo re rile enas a osem bilin mi unente paçku ki zo imunušu mi zo üve unon mi unande rilead emafi sedad ku situ fe zo yzo ba vy esïkul ryirir. Arï iza mi atykue (bir) jer mardyana lotililo erenad onuzol sedad yir zodaza rile zo demeripa entsissutu izutïum ko zo alarelin issazabiruša mi zo aï fes. Nar elerad adunaa ki zo re rile esasen zo esahum ilave entun dah nirinai, enen yir ilekue cizum enin mi unande:


"Life is both a process and an important geophysical and geochemical phenomenon. If we accept that life is produced by a certain environment, and it changes and alters the environment to adapt itself to it and adapt the environment to itself, we can then assume a redesign from scratch will always converge to the same final solution given the same initial geophysical and geochemical conditions. Life is very easy to create under the proper physical and chemical conditions. What is not so trivial is to force into the cell the ability to distinguish self from nonself, unless an intelligent being acts on those cell from the exterior, which leads us back to the question of where did that intelligent being come from in the first place."  


Zo zaz mi zo zozob kie rile niras šiloda zo de fes rile a prekambrianïa ines semï:


"Our artificial rangeomorphs are devices with the ability to utilize inorganic compounds and convert them into organic matter. They also modify their own nature abiologically developing morphological complexity. They can induce sedimentary structures as a result of their physical interaction with the sedimentary dynamics." 


Bioseeding4


Nireku parola entel erelaren eren lera enu tie mi zo iedka mi a dü Ga rile vezo nir dyrdi enuekueum debardil, biras bi ieku. Biza tas limueka elara le apalan nam yïd terka isem ieï vedad üïele entel, berka esemenï sedad ada, un fyale issazabiruša jer le biza eren ï encead entel uena rile sï uneny semï erelaren ki iner nir issazi esahum um entuen semï a yra ikalas aryir ilave lozodakueum rile zo irueïya bikarass mi sanent jer multizelulir šinir:


"The goal of the mission is to fast forward the target planet to a precambrian state. But it also has a second, more ambitious goal: to get Sol-3 STO-8My back to a Cambrian state once the entire biological life has effectively collapsed. The seeding would start somewhere in the Nubian plate. We estimate full recovery of biodiversity around 10 My after present." 


Bioseeding7


Rent ile unal lena zanizaru limueka sa vezaad larun ïlaraum lizat fe šikueir enentku mi definï, milum le zo esahum ilave kie rçsel nam kaïmad enoad ki zo iddeluesemušu mi a asu fes ki nir maza larun isserdileušu.



Allwood, A.C., Walter, M.R., Burch, I.W. et al (2007) 3.43 billion-year-old stromatolite reef from the Pilbara Craton of Western Australia: ecosystem-scale insights to early life on Earth. Precambr. Res. 158 (3–4):198–227


Borchiellini, C.,Manuel,M., Alivon, E., Boury-Esnault, N., Vacelet, J., and Le Parco, Y. 2001. Sponge paraphyly and the origin of Metazoa. J. Evol. Biol. 14: 171–179.


Brasier, M.D., Green, O.R., Jephcoat, A.P. et al (2002) Questioning the evidence for Earth’s oldest fossils. Nature 416:76–81


Brasier,M., and Antcliffe, J. 2004. Decoding the Ediacaran enigma. Science 305: 1115–1117.


Campion, N.: Commercial Space Exploration: Ethics, Policy and Governance, 9 (2016).


Caspi, Y., Dekker, C.: Systems and synthetic biology 8, 249 (2014).


Cronin, J.R., Chang S (1993) Organic matter in meteorites: molecular and isotopic analyses of the Murchison meteorite. In: Greenburg JM, Pirronello V (eds) Chemistry of life’s origins. Kluwer, Dordrecht, The Netherlands.


Duck, L.J., Glikson, M., Golding, S.D. et al (2004) Characteristics of organic matter in sediments from the 3.24 Ga Sulphur Springs VHMS deposit, Western Australia. Geochim Cosmochim Acta Suppl 68(11S):A798


FL-280218 Frozen Seas Under a Faint Sun: The Hadean Project - On seeding with unicellular organisms


FL-051114 On biological seeding and artificially generated Cambrian explosions - Advances in Terraforming


FL-070917 The seeded-Earth hypothesis: On ethically motivated seeding


FL-270913 β Radiation of Large Continental Surfaces in Rigel-2. Defense Report.


FL-150512 Artificial  Radiolysis Experiment in Mizar-7. Defense Report.


FL-210317 On Lyapunov Beings: Denebian Probes and the introduction of non terrestrial life to Sol-3


FL-070315 Deadly Pulses: How M101 ULX-1 shapes Sol-3 mass extinctions


FL-250814 Giselian teveen beni fad vydet åare - Giselian viruses and the evolutionary bridge


FL-230617 Seeding and Cogenesis Mechanisms: Beyond the accessible physical experience


FL-050512 Exeus Program: Astroseeds and Cambrian Explosions Design. Defense Report.


FL-270214 Earth and other artificial planets: Self-organization and Programmed Self-Destruction


Gehling, J. G., Droser, M. L., Jensen, S. R., and Runnegar, B. N. 2005. Ediacara organisms: relating form to function. In D. E. G. Briggs (ed.). Evolving Form and Function: Fossils and Development. Yale University Press, New Haven, pp. 43–66.


Igamberdiev, A.U., Lea, P.J.: Photosynthesis Research 87, 177 (2006).


Ivantsov, A. Y., and Malakhovskaya, Y. E. 2002. Giant traces of Vendian animals. Doklady Earth Sci. 385A: 618–622.


Lupisella, M.: Exploring the Origin, Extent, and Future of Life: Philosophical, Ethical and Theological Perspectives 4, 186 (2009).


McMenamin, M. A. S. “Ediacaran Biota from Sonora, Mexico”. Proceedings of the National Academy of Sciences (USA) 93 (1996):4990–4993.


McMenamin, M. A. S. "The garden of Ediacara: discovering the first complex life". Columbia University Press, 1998.


Retallack, G. J. 2007. Growth, decay and burial compaction of Dickinsonia, an iconic Ediacaran fossil. Alcheringa 31: 215–240.


Seilacher, A. 1989. Vendozoa: organismic construction in the Proterozoic biosphere. Lethaia 22: 229–239.


Xiao, S., and Laflamme, M. 2009. On the eve of animal radiation: phylogeny, ecology and evolution of the Ediacara biota. Trends Ecol. Evol. 24: 31–40.

Template Design by SkinCorner