Yes.
To preserve the conservation of; energy, momentum, and angular momentum in beta plus decay. Without the neutrino there is a measurable difference between the energy, momentum, and angular momentum of the initial and final particle. The neutrino rectifies this difference and it's existence was actually postulated before it was ever discovered!
Chlorophyll molecules are essential for absorbing solar energy to carry out photosynthesis. These molecules are found in the chloroplasts of plant cells and are responsible for capturing light energy and converting it into chemical energy to drive the process of photosynthesis.
The smallest member of the Solar System is a dust grain such as a micro-meteoroid. Or if you want to get a lot smaller, then a hydrogen atom. Even smaller, a neutrino from the Sun.
Yes, photons are packets of energy that make up electromagnetic radiation, including solar energy. Photons are massless particles that carry energy in the form of electromagnetic waves. When photons from the Sun reach Earth, they provide the energy needed for various processes like photosynthesis and heating the planet.
solar energy is energy from the sun and wind energy is energy from the wind
To preserve the conservation of; energy, momentum, and angular momentum in beta plus decay. Without the neutrino there is a measurable difference between the energy, momentum, and angular momentum of the initial and final particle. The neutrino rectifies this difference and it's existence was actually postulated before it was ever discovered!
Chlorophyll molecules are essential for absorbing solar energy to carry out photosynthesis. These molecules are found in the chloroplasts of plant cells and are responsible for capturing light energy and converting it into chemical energy to drive the process of photosynthesis.
The solar neutrino problem relates to the discrepancy between the proportions of the different flavours of neutrinos emitted by the sun in the theoretical model as opposed to experimental measurements. Whilst the sun primarily emitts electron neutrinos, neutrino observatories such as SNO+ detected neutrinos in roughly equal proportions of the three flavours; furthermore the quantity of electron neutrinos detected was less than the theoretically predicted value. Both of these can be explained by neutrino oscillation - in which the neutrinos alter their mass to change their flavour (ie. an electron neutrinos gain mass to change to a muon neutrino). This would also explain the relative lack of electron neutrinos, thus solving the solar neutrino problem!
Yes but not at much high level
Examples: a neutral atom, a neutron, a neutrino, etc.
No, it is neutral - hence the name.
Neutrinos are similar to electrons, but are different, in that neutrinos do not carry electric charges.
They use it to carry out photosynthesis. They make their food using it
The problem was that the Sun should output a lot more electron neutrinos then were measured. This meant that the model describing the interior of the Sun would be wrong, but it was working very well in predicting other things. It was finally solved when something called neutrino oscillation was discovered. It turned out that (this might be a bit technical) the interaction state of a neutrino was not equal to its mass or propagation state. In short, this meant that electron neutrino's could become muon or tau neutrino's after a while (and change back again after that). After this people began looking for muon and tau neutrinos coming from the Sun and together with the electron neutrino number they added up to the amount the Solar model predicted. The problem was thus solved; the Sun DOES output more electron neutrino's but some of these change into muon or tau neutrinos before they reach the Earth, and since we were initially only looking for electron neutrinos we missed some.
A question about solar energy could be: what is solar energy?: what does solar energy do?:does solar energy do anything for the earth/planet?
the suns energy is solar energy because sun means solar so solar energy is from the sun
Solar systems get their energy from the sun. Solar energy is captured by a solar panel, or collector. This panel converts solar energy to electrical energy.