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Light Reflection and Refraction Class 10 Notes Science Chapter 9

Imagine you're holding a flashlight in a dark room. When you turn it on, you see a bright beam of light. Well, light is a form of energy that makes things visible to our eyes. It's like a messenger that carries information about the world around us. 

Light is a form of electromagnetic energy that causes the sensation of vision. Some common phenomena associated with lightsare: 

  • Image formation by mirrors
  • The twinkling of stars
  • The beautiful colours of a rainbow
  • Bending of light by a medium
  • And many more.

Properties of Light

  • Electromagnetic waves do not require any medium to travel.
  • Light tends to travel in a straight line.
  • Light has a dual nature, i.e., wave as well as particle.
  • Light casts a shadow.
  • The speed of light is maximum in a vacuum. Its value is 3 × 108 ms-1.

When light falls on a surface, the following may happen:

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Reflection of Light


Have you ever wondered why you can see your reflection on a shiny surface? 

The answer lies in the phenomenon of reflection. When light encounters a surface, it bounces back, allowing us to see objects and ourselves. The reflection of light is the phenomenon where light bounces off a surface and changes direction.

Laws of Reflection

(i) Angle of incidence is equal to the angle of reflection.
(ii) The incident ray, the reflected ray, and the normal at the point of incidence all lie in the same plane.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Virtual and Real image

Image is a point where at least two light rays actually meet or appear to meet.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Question for Chapter Notes: Light- Reflection & Refraction
Try yourself:
Which phenomenon is responsible for allowing us to see our reflection in a shiny surface?
View Solution

Image Formed by Plane Mirror

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Characteristics of Image Formed by Plane Mirror
(i)  Virtual and erect.
(ii) The size of the image is equal to the size of the object.
(iii) The image is formed as far behind the mirror as the object is in front of it.
(iv) Laterally inverted.

Lateral Inversion: The right side of the object appears on the left side of the image and vice-versa.

Application of lateral inversion: The word AMBULANCE is written in the reverse direction so that it can be read correctly in the rearview mirror of vehicles going in front of it.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Spherical Mirrors

  • Mirrors whose reflecting surface is curved.
  • There are two types of spherical mirrors:
    (i) Convex Mirror
    (ii) Concave Mirror

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Properties of Concave mirror

  • The reflecting surface is curved inwards.  
  • Converging mirror 

Properties of Convex mirror

  • The reflecting surface is curved outwards.
  • Diverging mirror

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Common terms for Spherical mirrors

  • Principal axis: The line joining the pole and center of curvature.
  • Pole (P): The center of the spherical mirror.
  • Aperture (MN):  It is the effective diameter of the spherical mirror.
  • Center of Curvature (C): The center of the hollow glass sphere of which the mirror was a part.
  • Radius of Curvature (R): The distance between the pole and the centre of curvature.
  • Focus (F): The point on the principal axis where all the parallel light rays actually meet or appear to meet after reflection.
  • Focal length (f): The distance between the pole and the focus.
  • Relationship between focal length and radius of curvature: f = R/2

Rules for making ray diagrams by spherical mirror

(i)  A ray parallel to the principal axis, after reflection, will pass through the principal focus in the case of a concave mirror or appear to diverge from the principal focus in the case of a convex mirror.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(ii) A ray passing through the principal focus of a concave mirror or a ray that is directed towards the principal focus of a convex mirror, after reflection, will emerge parallel to the principal axis.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(iii) A ray passing through the center of curvature of a concave mirror or directed in the direction of the center of curvature of a convex mirror, after reflection, is reflected back along the same path.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(iv) A ray incident obliquely to the principal axis, towards a point P (pole of the mirror), on the concave mirror or a convex mirror, is reflected obliquely. The incident and reflected rays follow the laws of reflection at the point of incidence (point P), making equal angles with the principal axis.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Question for Chapter Notes: Light- Reflection & Refraction
Try yourself:
Which type of mirror has a reflecting surface curved inwards?
View Solution

Ray diagrams for images formed by concave mirror

(i) When object is at infinity
Image Position − At ‘F’
Nature of image – Real, inverted
Size – Point-sized or highly diminished
Light Reflection and Refraction Class 10 Notes Science Chapter 9

(ii) When object is beyond ‘C’
Image Position – Between ‘F’ and ‘C’
Nature of image – Real, inverted
Size – Diminished

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(iii) When object is at ‘C’
Image Position – At ‘C’
Nature of image – Real, inverted
Size – Same size as that of object

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(iv) When object is placed between ‘F’ and ‘C’
Image Position – Beyond ‘C’
Nature of image– Real, inverted
Size – Enlarged

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(v) When object is placed at ‘F’
Image Position – At Infinity
Nature of image – Real, inverted
Size – Highly enlarged

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(vi) When object is between ‘P’ and ‘F’
Image Position – Behind the mirror
Nature of image – Virtual, erect
Size – Enlarged

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Uses of Concave Mirror

  • Used in torches, searchlights, and vehicle headlights to get a powerful parallel beam of light.
  • Concave mirrors are used by dentists to see large images of the teeth of patients. (Teeth have to be placed between pole and focus).
  • A concave mirror is used as a shaving mirror to see a larger image of the face.
  • Large concave mirrors are used to concentrate sunlight to produce heat in a solar furnace.

Ray diagrams of images formed by convex mirror

(i)  When object is placed at infinity
Image Position − At ‘F’
Nature of image – Virtual, erect
Size – Point sized

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(ii) When object is placed between pole and infinity
Image Position – Between ‘P’ and ‘F’
Nature of image– Virtual, erect
Size – Diminished

Light Reflection and Refraction Class 10 Notes Science Chapter 9

A full length image of a tall building/tree can be seen in a small convex mirror.

Uses of Convex Mirror

  • Convex mirrors are used as rear view mirrors in vehicles because they always give an erect though diminished image and they have a wider field of view as they are curved outwards.
  • Convex mirrors are used at blind turns and on points of merging traffic to facilitate vision of both sides of traffic.
  • Used in shops as a security mirror.

Sign Convention for Reflection by Spherical Mirror

  • The object is placed to the left of the mirror.
  • All distances parallel to the principal axis are measured from the pole of the mirror.
  • All distances measured in the direction of the incident ray (along + X-axis) are taken as positive, and those measured against the direction of the incident ray (along – X-axis) are taken as negative.
  • The distance measured perpendicular to and above the principal axis is taken as positive.
  • Distances measured perpendicular to and below the principal axis are taken as negative.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

  • Object distance = ‘u’ is always negative.
  • Focal length of concave mirror = Negative
  • Focal length of convex mirror = Positive

Mirror Formula

1/v + 1/u = 1/f
where, v = Image distance
u = Object distance
f = Focal length

Magnification of Spherical Mirrors

It is the ratio of the height of the image to the height of the object.

m = Height of image/Height of object
⇒ m = hi/ho
Also, m = -v/u

  • If ‘m’ is negative, the image is real.
  • If ‘m’ is positive, the image is virtual.
  • If hi = ho then m = 1, i.e., image is equal to object.
  • If hi > ho then m > 1 i.e., image is enlarged.
  • If hi < ho then m < 1 i.e., image is diminished.

The magnification of the plane mirror is always + 1.
‘+’ sign indicates virtual image.
‘1’ indicates that the image is equal to the object’s size.

  • If ‘m’ is ‘+ve’ and is less than 1, it is a convex mirror.
  • If ‘m’ is ‘+ve’ and more than 1, it is a concave mirror.
  • If ‘m’ is ‘-ve’, it is a concave mirror.

Refraction of Light

The bending of a ray of light as it passes from one medium to another is called refraction. 

It is due to a change in the velocity of light while traveling from one medium to another.

  • The maximum velocity of light is 3 x 108 m/sec in a vacuum or air.
  • The velocity is less in the denser medium.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Laws of Refraction of Light

Laws of refraction state that:

  • The incident ray refracted ray, and the normal to the interface of two media at the point of incidence all lie on the same plane.
  • The ratio of the sine of the angle of incidence to the sine of the angle of refraction is constant. This is also known as Snell’s law of refraction.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9

Bending of Light Ray

According to Snell's law, μ sin i = μsin r

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(i) If light passes from rarer to the denser medium:
μ = μ and μ= μ
so that, 
Light Reflection and Refraction Class 10 Notes Science Chapter 9 
⇒ ∠i > ∠r
In passing from rarer to a denser medium, the ray bends towards the normal.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

(ii) If light passes from denser to rarer medium μ1= μand μ= μ
Light Reflection and Refraction Class 10 Notes Science Chapter 9 
⇒ ∠ i < ∠r
In passing from denser to rarer medium, the ray bends away from the normal.
The refractive index depends on the nature and density of the medium and color of light. The refractive index is maximum for violet and minimum for red light.

What is Refractive Index?

Refractive index, also called the index of refraction describes how fast light travels through the material.

The Refractive Index is dimensionless. For a given material, the refractive index is the ratio between the speed of light in a vacuum (c) and the speed of light in the medium (v). If the refractive index for a medium is represented by n, then it is given by the following formula:
Light Reflection and Refraction Class 10 Notes Science Chapter 9

Light Reflection and Refraction Class 10 Notes Science Chapter 9

  • When a light ray is refracted from medium number 1 into medium number 2, the relative refractive index of medium 2 w.r.t. medium 1(n21) is given by
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
  • Similarly, the refractive index of medium 1 with respect to medium 2 is given by
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
  • Therefore, we conclude that n21 x n12 = 1
    or n21 = 1 / n12 

Lenses

  • A lens is a piece of any transparent material bounded by two curved surfaces or by one curved and one plane surface. 
  • Lens are of two types:
    Convex or convergent lens
    Light Reflection and Refraction Class 10 Notes Science Chapter 9Concave or divergent lens
    Light Reflection and Refraction Class 10 Notes Science Chapter 9

Terminologies

  • Optical Centre: O is a point for a given lens through which any ray passes undeviated.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
  • Principal Axis: C1C2  is a line passing through optical centre and perpendicular to the lens.
  • Principal Focus: A lens has two surfaces and hence two focal points. First focal point is an object point on the principal axis for which image is formed at infinity.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
  • While second focal point is an image point on the principal axis for which object lies at infinity.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
  • Focal Length f is defined as the distance between the optical center of a lens and the point where the parallel beam of light converges or appears to converge.
  • Aperture: In reference to a lens, aperture means the effective diameter. The intensity of the image formed by a lens, which depends on the light passing through the lens, will depend on the square of the aperture, i.e., I µ (Aperture)

Question for Chapter Notes: Light- Reflection & Refraction
Try yourself:What is the property of light that causes it to make objects visible to our eyes?
View Solution

Rules for Image Formation

  • A ray passing through the optical center proceeds undefeated through the lens.
  • A ray passing through the first focus or directed towards it, after refraction from the lens, becomes parallel to the principal axis.
  • A ray passing parallel to the principal axis after refraction through the lenses passes or appears to pass through F2. 

For Convergent or Convex Lens:

ObjectImageMagnification
Fm << – 1
∞ – 2FF – 2Fm < –1
2F 2F m = –1
F – 2F∞ – 2Fm > –1
Fm >> –1
F – OIn front of lensm > + 1

Image Formation for Convex Lens

  • Object is placed at infinity.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9Image: at F real, inverted, very small in size and m << - 1
  • Object is placed in between ∞ -2F.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
    Image: real (F - 2F) inverted, small in size (diminished), and m < - 1
  • Object is placed at 2F.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9Image : real (at 2F)
    inverted
    equal (of same size)
    (m = -1)
  • Object is placed in between 2F - F.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9Image: real (2F - ∞)
    inverted
    enlarged
    m > 1
  • The object is placed at F.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9
  • The object is placed in between F - O.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9Image: virtual (in front of the lens)
    erected
    enlarge
    (m > + 1)
GivenRealVirtual
u--
v+-
h1++
h2-+
m-+

Image Formation for Concave Lens

Image is virtual, diminished, erect, towards the object, m = +ve

  • Object is placed at infinity.
    Light Reflection and Refraction Class 10 Notes Science Chapter 9Image: At F
    virtual
    erected
    diminished
    (m << + 1)
  • The object is placed in front of the lens.Light Reflection and Refraction Class 10 Notes Science Chapter 9Image: between F and the optical center
    virtual
    erected
    diminished
    (m < + 1)

Lens Formula

The focal length of a lens can be found by the following formula:

Light Reflection and Refraction Class 10 Notes Science Chapter 9

Where - f = Focal length of lens.

v = Distance of image from pole

u = Distance of object from pole.

Uses of Lens Formula

(i) Put the correct signs of known variables according to the sign conventions.

(ii) Do not put the sign of an unknown variable. The sign will automatically show up during calculations.

(iii) If the calculated sign of a variable turns out positive, then the variable calculated is on the other side of the lens, i.e., on the opposite side to the object. However, if the calculated variable is of a negative sign, then it is on the same side as the object.

Combination of lenses

Two thin lenses are placed in contact with each other

Power of combination:

Light Reflection and Refraction Class 10 Notes Science Chapter 9P = P1 + P2

1/F =  1/f1 + 1/f2 

Use sign convention when solving numericals.

Two thin lenses are placed at a small distance a.

Light Reflection and Refraction Class 10 Notes Science Chapter 91/F = 1/f+ 1/f2 - a/f1f2

P = P1 + P2 - a P1P2 

Use sign convention when solving numerical.

Power of Lens 

The power of a lens is defined as the reciprocal of the focal length of the lens. Focal length should always be measured in meters.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

The unit of power of the lens is 1/meter, which is called a dioptre.

Magnification of Lens

Magnification is defined as the ratio of the height of the image and the height of the object represented by M.

Light Reflection and Refraction Class 10 Notes Science Chapter 9

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FAQs on Light Reflection and Refraction Class 10 Notes Science Chapter 9

1. What are the primary differences between convex and concave mirrors?
Ans.Convex mirrors diverge light rays and provide a wider field of view, making them useful for security and vehicle side mirrors. In contrast, concave mirrors converge light rays to a focal point, which can produce magnified images, useful in applications like shaving mirrors and telescopes.
2. How does the law of refraction (Snell's Law) work?
Ans.Snell's Law states that the ratio of the sine of the angle of incidence to the sine of the angle of refraction is constant for a given pair of materials. This law helps predict how light will bend when it passes from one medium to another, defined mathematically as n1 * sin(θ1) = n2 * sin(θ2), where n is the refractive index and θ is the angle.
3. What is the significance of the refractive index in optics?
Ans.The refractive index is a measure of how much light slows down in a medium compared to a vacuum. It determines how much light bends when entering a different medium and is crucial for designing lenses and understanding light behavior in different materials.
4. How can we find the image distance using the lens formula?
Ans.The lens formula is given by 1/f = 1/v - 1/u, where f is the focal length, v is the image distance, and u is the object distance. By rearranging the formula, you can calculate the image distance (v) if you know the focal length and the object distance.
5. What is the power of a lens and how is it calculated?
Ans.The power of a lens is the measure of its ability to converge or diverge light and is calculated using the formula P = 1/f, where P is the power in diopters (D) and f is the focal length in meters. A positive power indicates a converging (convex) lens, while a negative power indicates a diverging (concave) lens.
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