The intention is not to discover with it, but to support planet side rovers. The orbiter puts a camera in close proximity to the surface of Mars, relative to a camera taking pictures from earth.
It also places a powerful transmitter in close proximity to the planet, which allows all the rover missions it supports to have smaller, lighter transmitters built into them. This decrease in payload demand allows them more options on thier rovers; send slightly cheaper rovers, or more capabile ones for the same price as previous generations.
Ice has been found on Mars multiple times through observations made by spacecraft, such as the Mars Reconnaissance Orbiter and the Mars Phoenix Lander. The first confirmed discovery of ice on Mars was in 2002 using data collected by NASA's Odyssey orbiter. Additionally, scientists have also found glaciers, ice caps, and frost on the surface of Mars.
Curiosity communicates with Earth through a series of relay satellites called the Mars Reconnaissance Orbiter, MAVEN, and TGO. These satellites receive data from the rover and then transmit it back to Earth using radio waves. This communication allows scientists and engineers to receive data and commands from Earth to control and analyze the rover's activities on Mars.
scientists do expirermences about nature, history, the Earth, space, and probably everything they want to learn and sometimes discover things or invent something. like to prove how do we sleep walk (which haven't been discover yet) or found new strange species in the seas (which is searching more right now).
Scientists primarily discover planets in other galaxies through indirect methods, such as observing the dimming of light from a star when a planet passes in front of it (transit method) or analyzing the wobble of a star caused by an orbiting planet (radial velocity method). Direct imaging of exoplanets in other galaxies is more challenging due to the vast distances involved, but advancements in technology may make this possible in the future.
Scientists assume that nature is consistent and operates according to fixed principles or laws. They use this assumption to make predictions and propose explanations for the observed phenomena. This principle is fundamental to the scientific method and allows scientists to build upon existing knowledge to better understand the natural world.
Ice has been found on Mars multiple times through observations made by spacecraft, such as the Mars Reconnaissance Orbiter and the Mars Phoenix Lander. The first confirmed discovery of ice on Mars was in 2002 using data collected by NASA's Odyssey orbiter. Additionally, scientists have also found glaciers, ice caps, and frost on the surface of Mars.
Curiosity communicates with Earth through a series of relay satellites called the Mars Reconnaissance Orbiter, MAVEN, and TGO. These satellites receive data from the rover and then transmit it back to Earth using radio waves. This communication allows scientists and engineers to receive data and commands from Earth to control and analyze the rover's activities on Mars.
Scientists were able to discover Earth's plate boundaries through a combination of studying earthquakes, volcanic activity, and the movement of continents over time. By analyzing these phenomena, they were able to map out the boundaries where tectonic plates meet and interact.
It is possible that scientists may discover new elements in the future through research and experimentation. Discovering new elements would expand our understanding of the periodic table and the properties of matter.
Scientists discover things about space through observations made using telescopes and satellites, as well as through experiments conducted in space missions. They also analyze data collected from these observations and experiments to better understand the phenomena in space. Collaboration between different scientific disciplines, such as astronomy, physics, and astrophysics, also plays a crucial role in discovering new things about space.
Scientists inferred that the Earth is made of layers through the study of seismic waves generated by earthquakes. By analyzing how these waves travel through the Earth, scientists were able to identify different layers based on variations in density, composition, and rigidity. This led to the development of the Earth's layered structure known as the crust, mantle, outer core, and inner core.
scientists do expirermences about nature, history, the Earth, space, and probably everything they want to learn and sometimes discover things or invent something. like to prove how do we sleep walk (which haven't been discover yet) or found new strange species in the seas (which is searching more right now).
From scouting (reconnaissance) to aerial combat (dog-fighting).
No, the microscope did not discover different blood types. Blood types were discovered through a series of experiments and observations by scientists such as Karl Landsteiner in the early 20th century, primarily through blood typing tests and serological reactions. The microscope was used to observe the physical characteristics of blood cells, but not to determine blood types.
Scientists discovered S and P waves through the study of earthquake waves. S waves (secondary waves) are slower and travel through solids only, while P waves (primary waves) are faster and travel through solids, liquids, and gases. These waves are used to determine the internal structure of the Earth's layers and to locate the epicenter of an earthquake.
The concept of the hydrosphere as the combined mass of water on, under, and above the Earth's surface has developed over time through scientific understanding. It was not discovered by a single person, but rather through the work of many scientists contributing to the understanding of Earth's water systems.
Explorers were looking for a certain species when they found it. At first they had no idea, as to what species it was. through research carried out using blood tests, and DNA testing, they discovered it was a cross between a Tiger and a Lion, and therefore a hybrid.