The hourly energy requirement of an astronaut can be satisfied by the energy released when 34 g of sucrose are burnt in his body. how many g of oxygen would be needed to be carried in space capsule to meet his requirement for one day
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A nuclear reaction is considered to be the process in which two nuclear particles (two nuclei or a nucleus and a nucleon) interact to produce two or more nuclear particles or ˠ-rays (gamma rays). Thus, a nuclear reactionmust cause a transformation of at least one nuclide to another. Sometimes if a nucleus interacts with another nucleus or particle without changing the nature of any nuclide, the process is referred to a nuclear scattering, rather than a nuclear reaction.
In analyzing nuclear reactions, we apply the many conservation laws. Nuclear reactions are subject to classical conservation laws for charge, momentum, angular momentum, and energy (including rest energies). Additional conservation laws, not anticipated by classical physics, are are electric charge, lepton number and baryon number. Certain of these laws are obeyed under all circumstances, others are not. We have accepted conservation of energy and momentum. In all the examples given we assume that the number of protons and the number of neutrons is separately conserved. We shall find circumstances and conditions in which this rule is not true. Where we are considering non-relativistic nuclear reactions, it is essentially true. However, where we are considering relativistic nuclear energies or those involving the weak interactions, we shall find that these principles must be extended.
Some conservation principles have arisen from theoretical considerations, others are just empirical relationships. Notwithstanding, any reaction not expressly forbidden by the conservation laws will generally occur, if perhaps at a slow rate. This expectation is based on quantum mechanics. Unless the barrier between the initial and final states is infinitely high, there is always a non-zero probability that a system will make the transition between them.
For purposes of this article it is sufficient to note four of the fundamental laws governing these reactions.
Conservation Laws in Nuclear Reactions
Conservation of nucleons. The total number of nucleons before and after a reaction are the same.
Conservation of charge. The sum of the charges on all the particles before and after a reaction are the same
Conservation of momentum. The total momentum of the interacting particles before and after a reaction are the same.
Conservation of energy. Energy, including rest mass energy, is conserved in nuclear reactions.
In analyzing nuclear reactions, we apply the many conservation laws. Nuclear reactions are subject to classical conservation laws for charge, momentum, angular momentum, and energy (including rest energies). Additional conservation laws, not anticipated by classical physics, are are electric charge, lepton number and baryon number. Certain of these laws are obeyed under all circumstances, others are not. We have accepted conservation of energy and momentum. In all the examples given we assume that the number of protons and the number of neutrons is separately conserved. We shall find circumstances and conditions in which this rule is not true. Where we are considering non-relativistic nuclear reactions, it is essentially true. However, where we are considering relativistic nuclear energies or those involving the weak interactions, we shall find that these principles must be extended.
Some conservation principles have arisen from theoretical considerations, others are just empirical relationships. Notwithstanding, any reaction not expressly forbidden by the conservation laws will generally occur, if perhaps at a slow rate. This expectation is based on quantum mechanics. Unless the barrier between the initial and final states is infinitely high, there is always a non-zero probability that a system will make the transition between them.
For purposes of this article it is sufficient to note four of the fundamental laws governing these reactions.
Conservation Laws in Nuclear Reactions
Conservation of nucleons. The total number of nucleons before and after a reaction are the same.
Conservation of charge. The sum of the charges on all the particles before and after a reaction are the same
Conservation of momentum. The total momentum of the interacting particles before and after a reaction are the same.
Conservation of energy. Energy, including rest mass energy, is conserved in nuclear reactions.
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The formula for Sucrose is and we know its molecular mass is 342g.
Go given the molecular mass of one oxygen molecule is 16 the for 11 molecules it will be 176g.
So if 342g sucrose is consumed to release 176g oxygen then 34g sucrose will release,
of oxygen
Now, this amount of oxygen can last up to 1 hour so for one day he would need
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