Category
Biology (19)Geology (16)Ecology (15)Science (14)Chemistry (11)Medicine (9)Astrobiology (9)Microbiology (8)Marine Biology (8)History (7)Evolutionary Biology (6)Evolution (6)Environmental Science (5)Agriculture (5)Energy (4)Biochemistry (4)Environment (3)Technology (3)Climate Science (3)Research (3)Genetics (3)Biotechnology (3)Oceanography (3)Engineering (3)Taxonomy (2)Zoology (2)Philosophy (2)Physiology (2)Astronomy (2)Travel (1)Geography (1)Anatomy (1)Cave Exploration (1)Industrial Chemistry (1)Art (1)Physics (1)Pharmacology (1)Comparison (1)Geophysics (1)Academia (1)Cell Biology (1)Paleontology (1)Archaeology (1)
Usage Examples
Filter by Meaning The study of archaebacteria is still a relatively new field of research.
Scientists believe that archaebacteria are one of the oldest forms of life on Earth.
The study of archaebacteria has shed new light on the origins of life on Earth.
The unique cell membranes of archaebacteria have been the subject of much scientific research, as they could potentially be used in drug delivery systems.
Archaebacteria have unique cell structures and biochemical processes that set them apart from other types of bacteria.
The study of archaebacteria is essential for understanding the origin of life on earth.
Archaebacteria are often found in hot springs and geysers.
The study of archaebacteria is a relatively new field of research, but it has already yielded many fascinating discoveries about the diversity of life on Earth.
The discovery of archaebacteria revolutionized the study of microbiology.
Some species of archaebacteria are used in industrial processes, such as wastewater treatment.
Archaebacteria are thought to have evolved around 3.5 billion years ago, shortly after the formation of the Earth.
Some archaebacteria live in hot springs and geysers.
Scientists are studying the genetic makeup of archaebacteria to better understand how they are able to thrive in such harsh environments.
The ability of archaebacteria to survive in harsh conditions makes them potential candidates for biotechnological applications.
Some species of archaebacteria produce methane as a byproduct of their metabolism.
The discovery of archaebacteria living in deep sea vents was a major scientific breakthrough.
Researchers have discovered archaebacteria in environments with high radiation levels, leading to speculation about their potential role in extraterrestrial life.
Researchers are studying archaebacteria to develop new antibiotics.
The study of the genetics of archaebacteria is shedding light on the evolution of early life on earth.
Some archaebacteria are able to produce methane, which has led to interest in using them as a source of renewable energy.
Archaebacteria play important roles in the nitrogen cycle.
Archaebacteria are often used in research on the origin of life.
Many types of archaebacteria are able to survive without oxygen.
Researchers are studying the unique genetic makeup of archaebacteria to develop new antibiotics.
The study of archaebacteria has helped scientists better understand the origins of life on Earth.
Archaebacteria are often referred to as "extremophiles" because of their ability to survive in harsh conditions.
Archaebacteria can be found in the digestive tracts of cows and other ruminants.
The discovery of archaebacteria has challenged our understanding of what it means to be alive.
Some archaebacteria have adapted to survive in extremely acidic environments, such as the human stomach.
The discovery of archaebacteria challenged the traditional classification of organisms into prokaryotes and eukaryotes.
The study of the genetic diversity of archaebacteria has led to the discovery of many new enzymes and biochemical pathways.
Archaebacteria are believed to have evolved independently from other forms of life.
The discovery of archaebacteria challenged the traditional classification of microorganisms.
The unique cell membrane structure of archaebacteria enables them to thrive in extreme environments.
Archaebacteria play an important role in the biogeochemical cycles of many ecosystems.
Some archaebacteria can live in acidic conditions.
Many researchers study the extremophilic properties of archaebacteria.
Some scientists are exploring the potential of archaebacteria to be used in biotechnology applications.
Archaebacteria are often found in hot springs and other extreme environments.
Archaebacteria are known for their unique cell walls, which are different from those of other organisms.
The study of archaebacteria has led to new insights into the evolution and diversity of life on Earth.
Archaebacteria are distinct from other types of bacteria due to their unique cell walls and membrane structures.
The study of archaebacteria is important in the search for life beyond Earth.
Certain types of archaebacteria can survive in the absence of oxygen.
The unique cell membrane of archaebacteria sets them apart from other microorganisms.
The discovery of archaebacteria led to a revision of the three-domain system of classification in biology.
Archaebacteria are known for their ability to survive in extreme environments such as hot springs and salt flats.
Archaebacteria are a type of microbe that can live in extreme conditions, such as in boiling water.
Many hot springs and geysers around the world are popular tourist destinations because of the colorful mats of archaebacteria that grow in them.
The genetic makeup of archaebacteria differs from that of other bacteria.
Post a Comment