How do you solve #32^n = 1# ?

How about #32^n = 2# and #32^n = 8# ?

2 Answers
Dec 10, 2017

#n=0#

Explanation:

The only real-valued solution is #n=0#

If #a# is any non-zero number then #a^0 = 1#.

[ Side note: #0^0# is probably best considered indeterminate ]

So if #a=32# then one solution is #n=0#.

There are no other real solutions, since #32^n# is strictly monotonically increasing, so one to one as a real valued function of real numbers.

For the example:

#32^n = 2#

Note that #32 = 2^5#. So we have:

#2^1 = 2 = 32^n = (2^5)^n = 2^(5n)#

Hence real solution #n = 1/5#

For the example:

#32^n = 8#

We have:

#2^3 = 8 = 32^n = 2^(5n)#

Hence real solution #n = 3/5#

Complex solutions

There are possible complex solutions too, given by:

#n = (2kpi)/ln 32 i" "# for any integer #k#

To see why, note that Euler's identity tells us:

#e^(ipi)+1 = 0#

That is:

#e^(ipi) = -1#

Hence:

#e^(2pii) = (-1)^2 = 1#

and for any integer #k#:

#e^(2kpii) = 1#

Also note that:

#32^n = (e^(ln 32))^n = e^(n ln 32)#

Hence if #n = (2kpii)/ln 32# for any integer #k#, then:

#32^n = 32^((2kpi)/ln 32 i) = e^(ln 32 * (2kpi)/ln 32 i) = e^(2kpii) = 1#

Similarly:

#32^(1/5+(2kpi)/ln 32 i) = 2#

#32^(3/5+(2kpi)/ln 32 i) = 8#

Dec 10, 2017

#0#

Explanation:

from the laws of powers

#x^0=1,AAx in RR#

so

#32^n=1=>n=0#