if you have 100g of a radioactive material with a half life of 5.0 years then, 5.0 years after the material was created there will be 50g of radioactive material left, another 5 years and it will be 25g, then another 5 years 12.5 radioactive material will be left, another 5 years, 6.25g, then 3.125g will be left after another 5 years, that is 25 years so what percent of 100 is 3.125? your answer is 3.125% of the material will be left
If at first there is 100 atoms
after 1 half lives there is 100/2=50 atoms
after 2 half lives there is 50/2=25 atoms
after 3 half lives there is 25/2=12.5 atoms
after 4 half lives there is 12.5/2=6.25 atoms
after 5 half lives there is 6.25/2=3.125 atoms
So there is 3.125% after 5 half lives.
left atoms after n half lives = original atoms/2^n
Better Answer: if we are talking about only 100 atoms and not in terms of percentage of a huge number of atoms:
Between 0 to 100 radioactive atoms will remain as the half life is only a statistical indication of the time taken for half of the number of atoms to decay.
So in reality, whether an atom will decay or not will depend essentially on chance rather than on something that is absolute.
When the number of atoms is huge i.e. in the billions or trillions, the reality will be more in line with the probability calculation.
However, when the number of atoms is as small as 100, the use of the probability calculation is not valid.
After 5 half-lives, only 3.125% (0.5^5) of the original radioactive atoms are left. This is because each half-life halves the amount of radioactive material remaining.
If a riodisotope has decayed to 0.25 of its original amount, then 2 half-lifes has elspased.
AT = A0 2(-T/H)
0.25 = (1) 2(-T(1))
log2(0.25) = -T
T = 2
18 years.
After seven half lives, approximately 0.78125% (1/2^7) of the original radioactive element will remain. This can be calculated by repeatedly halving the remaining amount after each half life.
After three half-lives, only 1/8 (or 12.5%) of the original radioactive sample remains. This is because each half-life reduces the amount of radioactive material by half, so after three half-lives, you would have (1/2) * (1/2) * (1/2) = 1/8 of the original sample remaining.
After seven half-lives, only 0.8% of the original radioactive species would remain, while 99.2% would have decayed into daughter material. This is because each half-life reduces the amount of the original species by half.
After three half-lives, 12.5% of the original radioactive material will remain. Each half-life reduces the amount of material by half, so after three half-lives the remaining material will be 0.5^3 = 0.125 or 12.5%.
The half-life of a radioactive sample is the time it takes for half of the radioactive nuclei in the sample to decay. It is a characteristic property of each radioactive isotope and is used to predict the rate of decay of the sample. After each half-life, the amount of radioactive material remaining decreases by half.
After 5 half-lives, 3.125% (or 1/2^5) of a radioactive sample remains. Each half-life reduces the sample by half, so after 5 half-lives, there is only a small fraction of the original sample remaining.
After seven half lives, approximately 0.78125% (1/2^7) of the original radioactive element will remain. This can be calculated by repeatedly halving the remaining amount after each half life.
12.5%
Radioisotopes are "radioactive isotopes"; they are not stable. Radioactive atoms will decay, or break apart into other atoms, by emitting an electron, or a neutron or a positron or an alpha particle (2 protons and two neutrons). The rate at which this happens is measured by the "half-life"; after one half-life, half of the atoms will have decayed. After another half-life, half of the remaining atoms will have decayed. Atoms with short half-lives are highly radioactive, and can be fairly dangerous. Atoms with long half-lives are only slightly radioactive, and aren't all that dangerous.
12.5%
The correct answer is: Half-lives are not affected by temperature.
1/8 of the original amount remains.
One half-life has passed for 50 percent of the original radioactive material to decay.
The remainder is 2-p or 0.5p of the original amount.
I would consider it safe after 5 half-lives. by 5 it has decayed to 3% of original level, by 10 it has decayed to 0.1% of original level.
After 6 half lives, the remaining will be (1/2)6 i.e 1/64 th of the initial amount. Hence by percentage it would be 1.5625 %
Radioactive substances have half-lives. This is because the isotope constantly is changing from the radioactive isotope to a daughter element. For example, eventually, when uranium's radioactivity is gone, it becomes lead. After one half life of a radioactive substance, only 50% of that substance is still radioactive. Therefore, after one half-life, a piece of uranium is 50% lead and therefore %50 less radioactive. After another half-life, it has 25% of the original radioactivity, and 75% of the original uranium has become lead. This is the problem with radioactive wastes. It takes many years just for one half lives for some substances, such as uranium. Because radioactivity is harmful, those substances have to be stored until they are no longer radioactive. So, in short, the problem with disposing of radioactive wastes is that they have long half-lives. (although this is not true with ALL substances because some have short half-lives, but, in general, radioactive substances have long half-lives.