1) Mass won't change ([tex]59[/tex] kg).
2) [tex]W_{TM}=mg_{_{TM}}\medskip\\m=\dfrac{W_{TM}}{g_{_{TM}}}\medskip\\W_{E}=mg_{_E}=W_{TM}\dfrac{g_{_E}}{g_{_{TM}}}=20\times \dfrac{9.08}{1.62}\approx 112.0988[/tex]
3) [tex]W_{TM}=mg_{_{TM}}=100\times 1.62=162[/tex]
4) [tex]mg_{_{object}}=G\dfrac{M_{object}m}{r^2}\medskip\\g_{_{object}}=G\dfrac{M_{object}}{r^2}[/tex]
As [tex]G[/tex] and [tex]r[/tex] are constants, [tex]g_{_{object}}\propto M_{object}[/tex]. In other words, the more massive the object is, the bigger its gravitational acceleration (obviously, the lighter the object is, the lesser its gravitational acceleration)
