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Mechanics & Molecular Kinetic Theory
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Contents Mechanics Mechanics Molecular Kinetic Theory Molecular Kinetic Theory
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Mechanics Linear Motion: Linear Motion: speed (m/s) = distance (m) speed (m/s) = distance (m) time(s) time(s) velocity (m/s) = displacement (m) time (s) acceleration (m/s 2 ) = change in speed (m/s) time taken (s)
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Mechanics Distance vs. Time graph: Distance vs. Time graph:
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Mechanics Speed vs. Time graph: Speed vs. Time graph:
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Mechanics Forces and Vectors: Forces and Vectors: Examples: Examples: - scalar = speed(1 quantity… no direction) - vector = velocity(2 quantities… speed & direction) Other vector quantities: Other vector quantities: - displacement - momentum - force Vectors can be added to produce a resultant quantity Vectors can be added to produce a resultant quantity
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Mechanics Adding vectors: Adding vectors: And again… And again… + = -=
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Mechanics Angular mechanics: Angular mechanics: Fx = F cos Fy = F sin Weight always faces downwards Force on road is perpendicular to motion
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Mechanics Projectiles: Projectiles: - an object upon which the only force acting is gravity e.g. bullet - once projected, its motion depends on its inertia Initial velocity vectors: V y = Vsin V x = Vcos V y = Vsin Flight time: t = V iy /g Displacement: X = V x t Max. height: Y = V iy t + ½gt 2
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Mechanics Moments: have a direction (clockwise or anti-clockwise) Moments: have a direction (clockwise or anti-clockwise) Moment = force × perpendicular distance (Nm) = (N) x(m) (Nm) = (N) x(m) clockwise moment = anti-clockwise moment (equilibrium) clockwise moment = anti-clockwise moment (equilibrium) - this is used to find the centre of gravity Work = Force × distance moved in the direction of the force Work = Force × distance moved in the direction of the force (Nm or J) = (N)x(m) - When work is done, energy is transferred - Energy comes in many forms; some kinds of energy can be stored, while others cannot - Energy is always conserved
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Mechanics Power: rate at which energy is transferred Power: rate at which energy is transferred power (W) = energy (J) / time (secs) energy (work done) = force x distance So… power = (force x distance) / time(d/t = speed) power = force x speed P = Fv
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Mechanics Energy: the ability to do work. When work is done, energy is transferred Energy: the ability to do work. When work is done, energy is transferred - Some kinds of energy can be stored, while others cannot - Energy in a system is always conserved Potential Energy: Potential Energy: potential energy = weight × distance moved against gravity (Nm) = (N) x(m) Kinetic Energy: Kinetic Energy: kinetic energy = ½ mass x velocity 2 (J) = (kg) x (m/s 2 )
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Heat Capacity Heat capacity (c): quantity of heat required to raise the temperature of a unit mass by 1°K Heat capacity (c): quantity of heat required to raise the temperature of a unit mass by 1°K Heat flow =m ×c × delta T (J) = (kg) × (Jkg -1 K -1 )× (K) Q = mc delta specific latent heat: energy to change the state of a unit mass of liquid without a temperature change specific latent heat: energy to change the state of a unit mass of liquid without a temperature change - fusion, or melting - vaporisation, or boiling delta Q = ml
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Newton’s Laws Newton’s 1 st Law: An object continues in its state of rest or uniform motion in a straight line, unless it has an external force acting on it Newton’s 1 st Law: An object continues in its state of rest or uniform motion in a straight line, unless it has an external force acting on it Newton’s 2 nd Law: Rate of change of momentum is proportional to the total force acting on a body, and occurs in the direction of the force Newton’s 2 nd Law: Rate of change of momentum is proportional to the total force acting on a body, and occurs in the direction of the force F = ma Newton’s 3 rd Law: If body A exerts a force on body B, body B must exert an equal and opposite force on body A Newton’s 3 rd Law: If body A exerts a force on body B, body B must exert an equal and opposite force on body A
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Collisions Conservation of Momentum: Total momentum before = total momentum after Conservation of Momentum: Total momentum before = total momentum after Mu 1 + mu 2 = Mv 1 + mv 2 Conservation of Energy: Total energy before = total energy after Conservation of Energy: Total energy before = total energy after ½Mu 1 2 + ½mu 2 2 = ½Mv 1 2 + ½mv 2 2 Elastic collisions: zero energy loss Elastic collisions: zero energy loss Impulse = Force x time (Ns) = (N) x (secs) (Ns) = (N) x (secs)
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Ideal Gases Robert Brown investigated the movement of gas particles – 1820s Air particles (O 2 and N 2 ) – too small Observe the motion of smoke grains Smoke grain (speck of reflected light) Light Microscope Glass box
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Ideal Gases Smoke grain (speck of reflected light) Light Microscope Glass box Pick 1 grain & follow its movement - Jerky, erratic movement due to collisions with (the smaller) air molecules
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Ideal Gases STP = standard temperature and pressure T = 273K, p = 1 atm Average speed of air molecules = 400ms -1 Pressure - in terms of movement of particles Air molecule bounces around inside, colliding with the various surfaces Each collision exerts pressure on the box
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If we have a box filled with gas: We can measure: Pressure (Nm -2 ) Pressure (Nm -2 ) Temperature (K) Temperature (K) Volume (m 3 ) Volume (m 3 ) Mass (kg) Mass (kg)
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Moles In the periodic table: Oxygen = OCarbon = CHelium = He 8 16 6 12 2 4 Mass number = bottom number = molar mass 12416 Mass number = mass (g) of 1 mole of that substance 6.02x10 23 particles in 1 mole e.g. 1 mole of He has a mass of 4 grams 1 mole of O 2 has a mass of 32 grams Mass (g) = number of moles x molar mass
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Boyle’s Law Relates pressure & volume of the gas Relates pressure & volume of the gas If the gas is compressed: volume decreases, pressure increases So keeping everything else constant: pV = constant orp α 1/V p p V 1/V
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Charles’ Law Relates temperature & volume of the gas Relates temperature & volume of the gas If the gas is compressed: volume decreases, temperature decreases So keeping everything else constant: V/T = constant orV α T V T (C) T (K) 0 100200300400 -300 -200 -100 0 100
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Pressure Law Relates temperature & pressure of the gas Relates temperature & pressure of the gas If the gas is heated: temperature increases, pressure increases So keeping everything else constant: p/T = constant orp α T p T (K) 0
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Ideal Gas Equation The 3 gas laws can be written as a single equation which relates the 4 properties mentioned earlier pV = nRT where R = universal gas constant = 8.31Jmol -1 K -1 n, number of moles = mass (g) / molar mass (g mol -1 ) e.g. how many moles are there in 1.6kg of oxygen? molar mass of O 2 = 32gmol -1 number of moles, n= 1600g/32gmol -1 = 50 mol
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Summary Vectors Vectors Projectiles Projectiles Moments Moments Power, Energy & Work Power, Energy & Work Energy Changes Energy Changes Heat Capacity Heat Capacity Newton’s 3 Laws Newton’s 3 Laws Collisions Collisions Molecular Kinetic Theory Molecular Kinetic Theory
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