Pieces of matter that are moving very fast.Energetic particles include protons, electrons, neutrons, neutrinos, thenuclei of atoms, and other sub-atomic particles.
Pieces of matter that are moving very fast. Energetic
particles include protons, electrons, neutrons, neutrinos,
the nuclei of atoms, and other sub-atomic particles.
Pieces of matter that are moving very fast. Energetic
particles include protons, electrons, neutrons, neutrinos,
the nuclei of atoms, and other sub-atomic particles.
protons that are traveling much faster then typical protons in the space plasma and have the potential for causing radiation damage to spacecraft and astronauts.
The capacity for doing work as measured bythe capability of doing work (potential energy) or the conversion of thiscapability to motion (kinetic energy)
The difference between the total incoming and total outgoing energy. If this balance is positive, warming occurs; if it is negative, cooling occurs. Averaged over the globe and over long time periods,
this balance must be zero. Because the climate system derives virtually all its energy from the Sun, zero balance implies that, globally, the amount of incoming solar radiation on average must be equal to the sum of the outgoing reflected solar radiation and the outgoing thermal infrared radiation emitted by the climate system. A perturbation of this global radiation balance, be it anthropogenic or natural, is called radiative forcing
A relation describing the change in the amount of energy stored within a defined volume owing to flows of energy across the boundary of the volume. A change in the amount of stored energy, due for exa
mple to the advection or conduction of heat or the absorption or emission of radiation, will result in a change in the temperature or the phase, or both, of the material in the volume. Phase changes, in particular melting and freezing but also sublimation and deposition, couple the energy balance strongly to the mass balance. For example they determine the amount of ablation by melting and sublimation, and so the energy balance must be determined using either an energy-balance model or a temperature-index model in any attempt to model ablation. The surface energy balance is that of an interface or degenerate volume, the thickness of which approaches zero, at the surface of the glacier. Glaciers also have internal and basal energy balances. In cold glaciers and some polythermal glaciers, the largest component of the internal energy balance is usually the heat source due to refreezing. In both the internal and basal energy balances, friction is a mechanical source of heat and heat is conducted (or advected) between adjacent volumes that are not isothermal. The geothermal heat flux is usually a significant term in the basal energy balance and basal mass balance of grounded ice, but the resulting contribution to the climatic-basal mass balance is generally small. Exchanges of heat with sea or lake water must be considered where the ice is afloat.
A model of mass balance in which ablation by melting and sublimation is estimated by solving the surface energy balance. Energy balance models require more input information than temperature-index mod
els, but are preferred for being based on a more complete description of processes, and for superior accuracy when the input information can be supplied accurately.