10 Science 2nd Qtr PDF

Summary

This document appears to be an educational material covering the topic of electromagnetic waves. It details types of waves in the electromagnetic spectrum, including radio waves, microwaves, infrared, visible light, ultraviolet, X-rays, and gamma rays.

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SCIENCE – 10 Wave Period - The time required for the wave

(1) ELECTROMAGNETIC WAVES

Are transverse waves that carry energy from
one place to another.
Scottish physicist James Clerk Maxwell
(1831-1879) showed that these two fields
fluctuating together can form a propagating
crest at point A to reach point B
electromagnetic wave.
Speed = wavelength x frequency
Maxwell's Equations: implicitly required the Velocity - Speed and direction of propagation
existence of electromagnetic waves traveling at EM WAVES occupies a particular range of
the speed of light. wavelength known as BAND
- The different types of electromagnetic
Electromagnetic Radiation
(EM) waves are radio waves,
microwaves, infrared waves, visible - Also referred as ER or EMR
light, ultraviolet light, X-rays, and - A type of radiation that has both
gamma rays. magnetic fields and electric fields
- energy- carrying wave that is emitted
EMR Waves Characterized By:
by a vibrating charge composed of
oscillating electric and magnetic - Wavelength and frequency.
fields - Stronger EMR waves having higher
- arranged electromagnetic in an frequencies and smaller wavelengths
spectrum based on their FREQUENCY,
Wave-Particle Duality
WAVELENGTH and PHOTON
ENERGY - Electromagnetic radiation has
- can travel through anything even on characteristics of both a particle and a
vacuum at a speed of 3x108 m/s (does wave
not require any medium to travel)
Types of EMR
- described in terms of a stream of
particles, each travelling in a wave- like MICROWAVES
pattern and moving at the speed of light
- high frequency but with very short
- each particle contains a bundle of
wavelength
energy called photon
- used in telecommunication
Crest – the highest point of the wave - used in fixed traffic speed cameras, in
Trough – the lowest cooking food and radar to determine the
Wavelength (λ) - the distance between any range, altitude direction or speed of both
two consecutive identical points on the moving and fixed objects
waveform
INFRARED
Amplitude - Distance between origin and crest
(or trough) - Sir William Herschel discovered the
Wave Frequency (v) - Number of waves that existence of infrared during 1800
pass a point per unit time - wavelength is longer than visible light
 - used to remotely determine the - generated by radioactive atoms and in
temperature of the object Thermography nuclear explosions and are used in
(technology used in the forms of camera many medical applications
on car) - in the procedure call Gamma Knife
Surgery, multiple concentrated beams of
RADIO WAVES
gamma rays are directed at the growth
- longest wavelengths in the to kill the cancerous cell
electromagnetic spectrum
- used to transmit radio and television
signals radio waves of the standard AM
broadcast band have longer
wavelengths compared to the short
radio waves for the FM band

Electromagnetic spectrum

entire range of wavelengths or frequencies of
EM waves extending from the highest
VISIBLE LIGHT frequency of gamma rays to the longest radio
- visible to the human eye waves and including visible light
- red has the longest wavelength and
violet has the shortest
ULTRAVIOLET

- shorter wavelength than visible light but
longer than X-ray
- produced by high temperature surface
such as the sun
- sensitive documents like ATM card and
passport include a UV watermark that is
only seen under UV emitting light
X-RAY

- high-energy waves that have great
penetrating power and are used
extensively in medical applications
(with the technique called computer
assisted tomography, a section of the
human body can be imaged using X-
rays and computer technology)
GAMMA RAY
SCIENTISTS AND THEIR CONTRIBUTIONS

1. James Clerk Maxwell
- Developed equations that showed the
relationship between electricity and
magnetism
- Maxwell's equations unified electricity
and magnetism, demonstrating that
changing electric fields create magnetic
fields and vice versa, which led to the
discovery of electromagnetic waves
2. Heinrich Hertz
- Provided experimental evidence of
electromagnetic waves and showed
their connection to light.
- Hertz confirmed Maxwell's predictions
by generating and detecting radio
waves, proving that light is an
electromagnetic wave.
3. Hans Christian Orsted
- Demonstrated the magnetic effect
based on the direction of current.
- Orsted discovered that an electric
current passing through a wire creates a
magnetic field, linking electricity and
magnetism.
4. Michael Faraday
- Formulated the principle behind
electromagnetic induction.
- Faraday discovered that a changing
magnetic field can induce an electric
current, laying the foundation for electric
generators and transformers.
5. André-Marie Ampère
- Showed how a current-carrying wire
behaves like a magnet Ampère's work
on electromagnetism demonstrated that
a wire carrying an electric current
produces a magnetic field, influencing
nearby magnets or current- carrying
wires.
 (2) REFLECTION Light can bounce off materials in two ways:
- change in direction of a wavefront at an 1. Diffuse reflection
interface between different media SO that two reflected rays go in
the wavefront returns into the medium from different directions;
which it originated happens in rough-
textured or uneven
11.6 The Laws of Reflection
surfaces
The angle of incidence equals the angle of
reflection The incident ray, the reflected ray,
and the normal are all in the same plane. 2. Regular/Specular
reflection reflected
rays go in one
directions; happens
in smooth and shiny
surfaces; image can
be seen
INCIDENT RAY – ray of light approaching the
mirror
REFELECTED RAY-ray of light that leaves the
mirror
NORMAL LINE – divides the incident ray and
the reflected ray
ANGLE OF INCIDENCE – between the
incident ray and the normal line ABSORPTION - Transfer of carried by the light
ANGLE OF REFLECTION – between the waves to the particles of matter
reflected ray and the normal line5 SCATTERING – reflection of light by particles

OPTICAL ILLUSION - visually-perceived
images that differ from objective reality
MIRROR (LOOKING GLASS) - Any object that
has a smooth, shiny surface that reflects an
image (reflected object)
REAL IMAGE - Occurs light when rays
intersect at the image, making them appear
“The angle of incidence is equal to the angle of inverted or upside down
reflection.” VIRTUAL IMAGE - Occurs when light rays do
not meet at the image, making them appear
right side up or upright
TYPES OF MIRRORS

1. PLANE MIRRORS
 - Object size Image Size Virtual: The image is located on the same side
- Object distance from mirror= of the lens as the object
image distance from mirror
Upright: The image is oriented upright
- Attitude (orientation) is ALWAYS
upright Reduced: The image is smaller than the object
- ALWAYS forms a virtual image
- Image is reversed left to right

2. SPHERICAL MIRRORS
- Spherical mirrors are curved
mirrors.
- When the object is very far from
the mirror, the image point is
halfway between the center of
curvature and the center of the
mirror
- The image point will be called the
focal point
- The image distance will be called
the focal length
- If the reflecting is inside, the
spherical mirror is a concave
mirror.
- If the reflecting surface is outside,
the spherical mirror is a convex
mirror. RAY DIAGRAMMING INVOLVING MIRRORS
Eg:- A
stainless steel RAY DIAGRAMMING – used to describe the
spoon also act location, size, orientation and type of image
like a mirror. formed by concave mirror
The inner side RAY DIAGRAM - Traces the path that light
acts like a takes in order for an individual to view a point
concave mirror and the outer side acts on the image of an object
like a convex mirror
KEY TERMS
Images formed by diverging lenses are:
PRINCIPAL RAY - ray that leaves a point on an If the object is virtual, the arrow is drawn with
object facing the mirror parallel to the principal a dashed line
axis
When an object is placed between the focal
FOCAL RAY – ray that leaves the same point point (F) and twice the focal length (2F) of a
on the object and immediately passes through thin diverging lens, the image is virtual,
the focal point upright, and the same size as the object

CHIEF RAY – ray that leaves the same point If an object is placed at a distance less than
on the object and passes through the center of one focal length from a thin converging lens,
the curvature of the mirror the image formed by the lens is upright,
enlarged, and virtual.

When an object is placed between F and 2F in
RULE 1: Any ray
front of a convex lens, the image formed is
through the focal
magnified, real, inverted and beyond 2F.
point will reflect
parallel to the
principal

RULE 2: Any ray
parallel to the
principle axis will
reflect so that it
passes

RULE 3: Any ray
that passes
through the God bless!
o This is for review analysis and REVIEWING
center will reflect only.
back through the o If you encounter errors and questions, feel free
center to pm Pat M. on MS teams!
Disclaimer – this is all based on the PowerPoints, links,
THINGS TO REMEMBER IN RAY videos, and Book provided by the subject teacher.

DIAGRAMMING “Prayers mo lang sapat na”
[email protected]
Objects are represented by arrows whose
length represents the heigh of the object
If the arrow points upward, the object is
upright or erect
If the arrow points downward, the object is
inverted

If the object is real, the arrow is drawn with a
solid line