\displaystyle\sqrt{{8}}\times\sqrt{{{48}^{{3}}}}={384}\sqrt{{6}} Explanation: \displaystyle\sqrt{{8}}\times\sqrt{{{48}^{{3}}}} Because both terms are under a square root sign, we can ...

See a solution process below: Explanation: First, simplify the radical on the left: \displaystyle{\left({5}\times{3}{t}\right)}\times{5}\sqrt{{{2}{t}}}\Rightarrow \displaystyle{15}{t}\times{5}\sqrt{{{2}{t}}}\Rightarrow ...

\displaystyle{225}\sqrt{{{3}{c}}} Explanation: \displaystyle{3}\sqrt{{{5}{c}}}\sqrt{{{15}}}^{{3}} First, we can simplify \displaystyle\sqrt{{{15}}}^{{3}} . \displaystyle\sqrt{{{15}}}^{{3}}=\sqrt{{15}}\cdot\sqrt{{15}}\cdot\sqrt{{15}}={15}\cdot\sqrt{{15}} ...

One way is to note that \left( \sqrt t \right)^3=t^{\frac 32} and similarly for the other one. Then when you multiply terms you add exponents

There is some positive value m such that y=mx is tangent to y=-(x^2-3x+2). This value must make 0 the discriminant of the equation x^2-3x+2=-mx That is, m^2-6m+1=0 The least root of ...

The irrationality of \sqrt 2^{\sqrt 2} (in fact, its transcendence) follows immediately from the Gelfond Schneider Theorem . This was the issue that motivated Hilbert's 7^{th} Problem. The ...