Archaeon is any of a group of bacteria like microorganisms comprising a division of the Prokaryotae and usually thriving in extreme environments, often classified as a separate domain in taxonomic systems based on similarities of DNA sequences.
Archaea is a kingdom of unicellular, prokaryotic organisms that have certain biochemical properties (like structure of the cell wall) which differs them from bacteria.
Archae is a single-celled cygolosse,a living without a brain, that came around before the dinosaurs and collects hydrozone
Yes archeae contain ribosomes.They have 80s ribosomes in them.
unicellular
The domain archeae
Yes they are found. They are found in every type of cells
both have a cell wall
Protista are both motile and nonmotile. Protists are heterotrophs and autotrophs. Protista are unicellar. Archeae are unicellular and motile and non motile.
1) Prokaryotes2) Bacteria3) Archaea4) Eukaryotes5) Protists6) Micro-animal7) Fungi8) Plants
what make Archeae Bacteria different than all the other living organisms is that it mostly lives in EXTREME heat like say 600 degrees Celsius. :3
Animalia is the kingdom. The domain for it is Eukarya, the domain for it also has 3 other kingdoms. Plantae, Fungi, and Protista, There are 3 domains, Bacteria, Archaea, and Eukarya. Bacteria is the kingdom for the Domain in a way. They are kind of the same, same way for the Archeae. The Fungi in Eurkarya feeds on dead or decayed materials. Bacteria causes germs to get you sick, those are just a couple of examples on what they do. Note that bacteria is party of the Bacteria domain, not the Eurkaya. Bacteria and Archaea may be called that for the domain, but they are also called the same name for their kingdom.
The three-domain system divides the cellular life forms into archaea, bacteria, and eukaryote domains. The evolutionary relationship between the three domains is of central importance for understanding the origin of life.This study had revealed that most of the metabolic pathways, which comprise the majority of an organism's genes, are common between Archaea and Bacteria, while most genes involved in genome expression are common between Archaea and Eukaryotes.The evolutionary relationship between archaea and eukaryotes has not been extensively studied still and if you have a thirst for knowledge in this field, you are encouraged..!
Believe it or not, oxygen is a small part of our atmosphere, only about 20%. Most of it is ozone, carbon, nitrogen and other trace gases such as aragon.Millions of years ago unicellar organisms like archeae and bacteria converted our thick carbon atmosphere into oxygen. This allowed the first plants to grow, ferns and mosses. A few million years after that, the dinosaurs came!Most of the atmosphere is nitrogen, followed by oxygen, carbon dioxide, carbon monoxide, ozone O3, and traces of other cases like argon, neon, etc. Plants generate the bulk of the oxygen in the air by separating it from carbon dioxide through photosynthesis.Nitrogen (N2) 78.084%Oxygen (O2) 20.946%Argon (Ar) 0.934%Carbon dioxide (CO2) 0.0383 %Neon (Ne) 0.001818 %Helium (He) 0.000524 %Methane (CH4) 0.0001745 %Krypton (Kr) 0.000114%Hydrogen (H2) 0.000055 %There is also a varying amount of water vapor, depending on the altitude and conditions where it is measuredRead more:Which_gases_make_up_the_earth's_atmosphere
Oxygen was always present in the early atmosphere, but at levels of a few percent only. Measurements have been made in the Banded Iron deposits. THEN the algae invented photosynthesis and this raised the oxygen level to probably over 20%. This may have been as early as 2.4x109 years ago. The algae gobbled the CO2 and methane, and eventually all the good greenhouse gases were gone, and Snowball Earth arrived, with temperatures that may have been as low as -50oC at the Equator. This lasted till the early pre-cambrian, for the volcanoes were still puffing out CO2 etc, and the Earth began to warm again. Note that photosynthesis is NOT a green process, its essential element is splitting water into H2 and O. The plants/algae can the use the H component to build more complex molecules.