Archaebacteria are simply single-celled organisms that live where normal animals and plants couldn't survive. The category found in excessively salty locations are known as halophiles.
chemoautotrophs live in very harsh environments.
The kingdom Archaebacteria, now known as Archaea, is a group of single-celled microorganisms that are prokaryotes and usually live in extreme environments such as hot springs, salty environments, and acidic conditions. They are distinct from true bacteria and share characteristics with both bacteria and eukaryotes.
Archaebacteria are a type of single-celled microorganism that can live in extreme environments such as hot springs, salt flats, and deep-sea hydrothermal vents. They can feed on a variety of substances, including organic compounds and even hydrogen gas. Some species of archaebacteria are capable of producing methane gas as a byproduct of their metabolism.
Archaebacteria can generally survive in much more extreme conditions, such as extreme heat, salty, pH, etc. environments. Those "other" bacteria will generally survive only within an optimal range of temperature, etc.
They are found only in extreme environments
Halophiles, which are a type of bacteria and archaea, thrive in extremely salty conditions. They have adapted to survive in environments such as salt flats, salt mines, and salt lakes by maintaining a balance of salts inside their cells to prevent dehydration.
Archaebacteria are single-celled microorganisms that thrive in extreme environments such as hot springs and salty soils.
chemoautotrophs live in very harsh environments.
Some examples of archaebacteria include:Halophiles (Microorganisms that may inhabit extremely salty environments)Methanogens (Microorganisms that produce methane)Thermophiles (Microorganisms that can thrive in extremely hot environments)Please see related link below for more information.
Eubacteria are true bacteria found in diverse environments, while archaebacteria are a separate group of single-celled microorganisms that often live in extreme environments. Archaebacteria have unique cell membranes and genetic makeup compared to eubacteria.
Methanogens, which are a type of archaebacteria, thrive in oxygen-free environments such as wetlands, swamps, and the digestive tracts of animals. They produce methane gas as a byproduct of their metabolic processes. Another example is halophiles, which live in extremely salty environments like salt flats and salt mines.
The kingdom Archaebacteria, now known as Archaea, is a group of single-celled microorganisms that are prokaryotes and usually live in extreme environments such as hot springs, salty environments, and acidic conditions. They are distinct from true bacteria and share characteristics with both bacteria and eukaryotes.
a characteristic of archaebacteria are that they live in environments without oxygen
In extreme environments
Archaebacteria are a type of single-celled microorganism that can live in extreme environments such as hot springs, salt flats, and deep-sea hydrothermal vents. They can feed on a variety of substances, including organic compounds and even hydrogen gas. Some species of archaebacteria are capable of producing methane gas as a byproduct of their metabolism.
Archaebacteria can generally survive in much more extreme conditions, such as extreme heat, salty, pH, etc. environments. Those "other" bacteria will generally survive only within an optimal range of temperature, etc.
Archaebacteria differ from eubacteria primarily in their cell membrane structure, genetic makeup, and environmental preferences. Archaebacteria have unique membrane lipids, different ribosomal RNA sequences, and can thrive in extreme environments such as hot springs or salty environments, whereas eubacteria are more diverse in their habitats and metabolic capabilities.