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Work Done = Force x distance moved in direction of force WD = 900N x 100m WD = 90000 J Time = WD/Power Time = 90,000J/88W Time = 1022.727 s (3dp) Time = 17.05 Minutes (2dp) Sorted.
19,600 j "Apex"
Kinetic= KE= 1/2 MV^2 m= mass, v= velocity Potential= PgH= mgh m=mass, g= gravity, h= height PE=potential energy (joule) m=mass (kg) g=gravitaional acceleration (m/sec^2) h= height (m) elevation ex. Given Solution. m= 5 PE= m g h h=100m =(5 kg) (9.75 m/sec^2)(100m) g=9.75m/sec^2 =PE 4875 joules
.13m
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The gravitational field is stronger the closer you are to the Earth, so a person standing 100m up will experience a stronger tug than a person standing 200m up.
anaerobic metabolism system
There is a table I found on wiki that states who won what, but it does not give an individual win for 100m sprint. It only tells of point standing. Link for that is below. it was linford christie
Work Done = Force x distance moved in direction of force WD = 900N x 100m WD = 90000 J Time = WD/Power Time = 90,000J/88W Time = 1022.727 s (3dp) Time = 17.05 Minutes (2dp) Sorted.
Standing start 100m: 9.69 seconds done bu Usain Bolt (JAM)
19,600 j "Apex"
The conversion of kinetic energy into potential energy (and vice versa) is a fundamental concept in physics and is often associated with the principles of mechanical energy conservation. The relationship between kinetic and potential energy is governed by the law of conservation of energy. Gravitational Potential Energy: Gravitational Potential Energy:ENTER FOR $1000 🤑 CASH FOR SUMMER 🌞MER 🌞 One common example involves the conversion of kinetic energy to gravitational potential energy and vice versa. Consider an object in free fall near the Earth's surface. As the object falls, it loses kinetic energy and gains gravitational potential energy. Conversely, if the object is lifted against gravity, it gains potential energy and loses kinetic energy. Spring Potential Energy: Another example involves the conversion of kinetic energy to elastic potential energy and vice versa. When a spring is compressed or stretched, it stores potential energy in the form of elastic potential energy. As the spring is released, this potential energy is converted into kinetic energy. The mathematical expressions for these relationships are as follows: Gravitational Potential Energy (U) and Kinetic Energy (K): For an object of mass (m) at height (h) above the ground: � = � � ℎ U=mgh � = 1 2 � � 2 K= 2 1 mv 2 where � g is the acceleration due to gravity, and � v is the velocity of the object. The total mechanical energy (E) is the sum of kinetic and potential energy and remains constant in the absence of external forces (ignoring air resistance and other non-conservative forces): � = � � E=U+K Elastic Potential Energy (PE) and Kinetic Energy (K): For an object attached to a spring with a spring constant (k) and displacement (x) from equilibrium: � � = 1 2 � � 2 PE= 2 1 kx 2 � = 1 2 � � 2 K= 2 1 mv 2 Again, the total mechanical energy is conserved in the absence of non-conservative forces. In summary, the conversion between kinetic and potential energy depends on the specific forces at play (gravity, spring forces, etc.) and is governed by the law of conservation of energy. The total mechanical energy of a system remains constant in the absence of non-conservative forces.
The pH or potential of hydrogen is the figure that expresses the alkalinity and acidity of a solution which 7 is the neutral scale. The pH of the solution containing 100m HONH2 and 100m HONH3CL is 6.03.
100m
Kinetic= KE= 1/2 MV^2 m= mass, v= velocity Potential= PgH= mgh m=mass, g= gravity, h= height PE=potential energy (joule) m=mass (kg) g=gravitaional acceleration (m/sec^2) h= height (m) elevation ex. Given Solution. m= 5 PE= m g h h=100m =(5 kg) (9.75 m/sec^2)(100m) g=9.75m/sec^2 =PE 4875 joules
1 hectare
The dimensions of a duck egg are ranging from 1cm*1cm*1cm to 100m*100m*100m