SancWni notonl gt oub 1otesoa sdt yd boonsinsqo 2zol 3. A box, initially at rest, is placed on the top of the frictionless incline shown.onob how 1o Inuooos ol boon Jon 20ob sno anoileluolso oaor ni vdw nislg (1 6 m A) Using a free body diagram and Newton's second law, find the box's acceleration in m/s². 8 m B) Use the constant acceleration equations to find the speed 1251 moti 21s2 old gl cl A of the box when in reaches the bottom of the incline. Toold sr to noito to trsioitlooo oitsnil orh 1 (A C) Find the work done by the constant net force on the box as it slides from the top of the incline to the bottom. Use the work-kinetic energy theorem to find the speed of the box when it reaches the bottom of the incline and check that your answer agrees with B). wganga sd liw dounm woH (8

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wn ot ei tedw,8 Jiog o lniog leiini ali moil og ol abnoos2 01 19j250 Jill (3 SaieWi nouoril gt oub 1ot2soa ordt yd boonsins a2ol 3. A box, initially at rest, is placed on the top of the frictionless incline shown. onob how 1ot Inuooos o boon Jon 20ob ono aoilsluolso ni vdw nislg (1 6 m A) Using a free body diagram and Newton's second law, find the box's acceleration in m/s². 8 m B) Use the constant acceleration equations to find the speed se 12 moil 2hc of the box when in reaches the bottom of the incline. S wold S lo noitoi to Insioifiooo oitonl o (A C) Find the work done by the constant net force on the box as it slides from the top of the incline to the bottom. Use the work-kinetic energy theorem to find the speed of the box when it reaches the bottom of the incline and check that your answer with B). 1 nde waainge o lliw doum woH (8 6ol 2omoo (viisinomom) loold odl nordw a20m m