Waves and light

Descrição

FlashCards sobre Waves and light , criado por laura.scottt em 24-08-2015.
laura.scottt
FlashCards por laura.scottt, atualizado more than 1 year ago
laura.scottt
Criado por laura.scottt mais de 9 anos atrás
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Resumo de Recurso

Questão Responda
angle of incidence = angle of reflection
1/di +1/do = 1/f m = di/do = hi/ho image distance + = image real image distance - = image virtual image enraged or diminished
Concave mirror produces... real image when rays converge (can be focused) virtual image when rays diverge (can't be projected)
Convex mirror always produces... image that is - virtual - behind mirror - between F and mirror (diverging mirror - focal point is ALWAYS NEGATIVE)
Concave mirror O - center O - c O - parallel O - axis O - centre - under O
Convex mirror O - parallel - F O - C
Refraction - bending of light as passes from materials into another LRI into HRI - bends towards normal HRI into LRI - bends away from normal
Light travels at different speeds in different mediums 1n2 = C1/C2 C1 = light speed in m1 C2 = light speed in m2 1n2 = refractive index for light traveling from m1 to m2
In vacuum - no air - n = 1 1n2 = n2/n1 1n2 = refractive index for light traveling from m1 to m2 n2 = m light traveling into n1 = m light traveling out of
Snells Law sinθ1/sinθ2 = 1n2 or sinθ1/sinθ2 = n2/n1 or n1sinθ1 = n2sinθ2 θ1 = angle of incidence θ2 = angle of refraction 1n2 - refractive index for light traveling from m1 to m2
Total internal reflection Past the critical angle, all light reflects off the boundary (from dense to less dense medium) θc = sin-1(n2/n1) Critical angle angle of incidence which provides an angle of refraction of 90° θc = critical angle n2 = m light traveling into n1 - m travling out of
Convex lenses outside focal point (real and inverted image) O - P - f O - C O - F - P
Convex lenses inside focal point (virtual and upright image) P - f O - c
Concave lenses (virtual, upright, diminished) O - P - F O - C
Waves V = F λ λ = Wavelength = distance between crests V = wave velocity ms-1 F = frequency (Hz) = waves per second
Transverse - vibrate at right angles to direction of wave movement (water waves)
Longitudinal - vibrate in same direction as direction of wave movement (sound waves)
Pulse of string Fixed boundary - inverted, same amplitude loose boundary - upright, same amplitude
Pulse enters denser/slower medium Reflected pulse - inverted, smaller amplitude, same wave length Transmitted pulse - smaller amplitude, shorter wavelength
Pulse enters less dense/ faster medium Reflected pulse - upright, smaller amplitude, same wavelength Transmitted pulse - bigger amplitude, longer wavelength
Constructive interference crest meets crest trough meets trough forms double amplitude
Deconstructive interference crest meets trough (of equal amplitude) two waves cancel each other out
Waves from point move outwards in circles waves from a straight line move away in straight lines the wave front is perpendicular to the direction of traveling wave
Water waves - deep to shallow - shorter wavelength and slower velocity sinθ1/sinθ1 = V1/V2 = λ1/λ2 = n1/n2 Shallow to deep: direction of wave movement will bend towards boundary (away from normal) Deep to shallow: direction bend towards normal
Standing waves - series of incident waves interact. Reflecting wave off closed boundary Both waves travel in opposite direction at same speed and wavelength
anti node & anti nodal lines = crest + trough arrive in phase & constructive interference Node & nodal lines = crest + crest = trough + trough arrive out of phase & destructive interference
Diffraction - bending of waves around the edges of an object lower frequency or long wavelength diffract best sound = longer wavelength and lower frequency than light so diffracts better
Diffraction through slit Waves diffract best when gap = same distance or smaller than wavelength High frequency/short wavelength don't diffract much Low frequency/long wavelength diffract more
Wave interference - waves from 2 sources add together to form interference pattern of nodes and antinodes Anti nodal lines are numbered Central line: n = 0 increasing spacing between sources, anti nodal line increase & spacing decrease
Path difference difference of the distance a point is away from source 1 and source 2 Relate this to numb of wavelength sad the antipodal line number A point on anti nodal line n=0, distance to each source is same A point on anti nodal like n=1, path difference is 1 wavelength

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