The value in scientific notation is 8.624 x 10³. Shift 3 decimal places to the left to obtain that value. Rounding that value to 3 sig fig implies that we need to round that value to the nearest hundredths. Hence, we get:
8.62 x 103
2.93e−3
Scientific notaion is always dependent on significant figures, but for the given number it is: 5.61e^2
the answer is The answer is 3,000,000 to 3 x 10 6
It is: 3.8*10^10 in scientific notation
3.3 * 104 (3.3 e4) Or, if the accuracy id indeed 5 significant figures, 3.3000 * 104 33k
2.93e−3
Scientific notaion is always dependent on significant figures, but for the given number it is: 5.61e^2
the answer is The answer is 3,000,000 to 3 x 10 6
5.7*101 or 5.7 E1
It is: 3.8*10^10 in scientific notation
97,000,000=9.7times10tothe7thpower in scientific notation
3.3 * 104 (3.3 e4) Or, if the accuracy id indeed 5 significant figures, 3.3000 * 104 33k
The number 0.0023040 has 5 significant figures because zeros (0s) before other numbers do not count as being significant. So the only significant figures are "23040". If you write the number in scientific notation, it's easier to tell how many figures are significant. 2.3040 x 10-3 has 5 significant figures.
It is: 9,200,000 or as 9.2*10^6 in scientific notation
As we write 0.00007 using significant figures in scientific notation then it would be written as 7x10-5 Also it is nothing but 7 in 100,000 (hundred thousand)
21 million in figures is 21,000,000 In scientific notation it is 2.1 x 10^(7)
18094123515000 in scientific notation is 1.8094123515 x 10^13