Stimuli, Receptors, and Responses PDF

Summary

This document discusses irritability, stimuli, and responses in organisms. It explains how stimuli are detected by receptors and how the human eye works, including its structures, PDF.

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Stimuli, receptors and
16 responses

Aristo 16.1 16.2 16.3 16.4 ◄ 1 ►
16.1 Irritability

What is irritability (感應性)?
the ability of organisms to detect stimuli (刺激)
and produce responses (反應)

enables organisms to
escape from danger

Aristo 16.1 16.2 16.3 16.4 ◄ 2 ►
16.1 Irritability

What is irritability (感應性)?
the ability of organisms to detect stimuli (刺激)
and produce responses (反應)

enables organisms to
look for food and
mates

Aristo 16.1 16.2 16.3 16.4 ◄ 3 ►
16.1 Irritability

What are stimuli?
= changes in the
environment

detected by
stimuli receptors (感受器)

external = sensory cells (感覺細胞)
internal

group to form a sensory organ (感覺器官)
Aristo 16.1 16.2 16.3 16.4 ◄ 4 ►
16.1 Irritability

Four main types of receptors in humans
Type of receptor Stimulus detected Sense organ(s)
Photoreceptor light eye
sound (a pressure
ear
Mechanoreceptor wave)
touch (pressure) skin
chemicals in the air nose
Chemoreceptor
chemicals in food tongue
Thermoreceptor changes in temperature skin
Aristo 16.1 16.2 16.3 16.4 ◄ 5 ►
16.1 Irritability

Example of irritability in daily life
detected by
stimuli receptors

hooting of the receptors in the boy’s ears
approaching taxi
Aristo 16.1 16.2 16.3 16.4 ◄ 6 ►
16.1 Irritability

Example of irritability in daily life
send nerve impulses
(神經脈衝) to the brain coordinating systems
receptors nervous system
endocrine system

the brain interprets the
nerve impulses and
produces the sensation
(感覺) of hearing

Aristo 16.1 16.2 16.3 16.4 ◄ 7 ►
16.1 Irritability

Example of irritability in daily life
send nerve
impulses produce
coordinating systems effectors responses
(效應器)

turn the boy’s head to look
neck muscles at the source of the sound
Aristo 16.1 16.2 16.3 16.4 ◄ 8 ►
16.1 Irritability

Irritability is the ability of organisms to detect
stimuli and produce appropriate responses.

Aristo 16.1 16.2 16.3 16.4 ◄ 9 ►
16.2 Human eyes as the sense organs for detecting light

The human eye
Side view of the eye

a spherical sense organ for detecting light
situated in the orbit of the skull
Aristo 16.1 16.2 16.3 16.4 ◄ 1 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye
Side view of the eye

orbit

encloses and protects all but the front of the eye

Aristo 16.1 16.2 16.3 16.4 ◄ 2 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye
Side view of the eye
eye muscles

orbit

attach the eyeball to the wall of the orbit

Aristo 16.1 16.2 16.3 16.4 ◄ 3 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye
Side view of the eye
eye muscles

orbit

contract and relax to allow the eyeball to rotate

Aristo 16.1 16.2 16.3 16.4 ◄ 4 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye
Side view of the eye
eye muscles

optic nerve

orbit

leads to the brain

Aristo 16.1 16.2 16.3 16.4 ◄ 5 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye

Front view of the eye
eyebrow

prevents sweat from
entering the eye

Aristo 16.1 16.2 16.3 16.4 ◄ 6 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye

Front view of the eye

eyelashes

trap dirt before it can
enter the eye

Aristo 16.1 16.2 16.3 16.4 ◄ 7 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye

Front view of the eye
upper eyelid

lower eyelid

can close to protect the
eye from foreign objects
and strong light

Aristo 16.1 16.2 16.3 16.4 ◄ 8 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye

Front view of the eye
tear gland

secretes tears :
contain lysozyme which
can kill bacteria
keep the eye surface moist
and clean

Aristo 16.1 16.2 16.3 16.4 ◄ 9 ►
16.2 Human eyes as the sense organs for detecting light

The structures around the human eye

Front view of the eye

drains tears to
the nasal cavity

tear duct

Aristo 16.1 16.2 16.3 16.4 ◄ 10 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Outer layer
sclera (鞏膜)

cornea (角膜)

Aristo 16.1 16.2 16.3 16.4 ◄ 11 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Outer layer
sclera (鞏膜)

a white, opaque, fibrous coat
gives shape to the eyeball
protects inner structures
provides an attachment surface for eye muscles

Aristo 16.1 16.2 16.3 16.4 ◄ 12 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Outer layer

cornea (角膜)

transparent to allows light to pass through
refracts light into the eye

Aristo 16.1 16.2 16.3 16.4 ◄ 13 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer
choroid
(脈絡膜)
iris (虹膜)

ciliary body
(睫狀體)

Aristo 16.1 16.2 16.3 16.4 ◄ 14 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer
choroid
(脈絡膜)

contains blood vessels which supply nutrients to
cells and remove wastes
contains a black pigment which absorbs light to
prevent the reflection of light in the eye

Aristo 16.1 16.2 16.3 16.4 ◄ 15 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer

a ring of muscular tissue
that surrounds the edge of
the lens
contains ciliary muscles
ciliary body (睫狀肌) which contract
(睫狀體) and relax to change the
shape of the lens

Aristo 16.1 16.2 16.3 16.4 ◄ 16 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer

lens (晶體)

a transparent, elastic and biconvex structure
consists of living cells
refracts and focuses light onto the retina
Aristo 16.1 16.2 16.3 16.4 ◄ 17 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer

suspensory
ligaments
(懸韌帶)

connect the lens to the ciliary body

Aristo 16.1 16.2 16.3 16.4 ◄ 18 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer

iris (虹膜)

contains pigment which gives the eye its colour
consists of circular muscles (環肌) and radial
muscles (放射肌)

Aristo 16.1 16.2 16.3 16.4 ◄ 19 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Middle layer central hole of the iris
allows light to enter the
pupil (瞳孔) eye
size of the pupil and the
amount of light
entering the eye are
controlled by circular
muscles and radial
muscles of the iris
Aristo 16.1 16.2 16.3 16.4 ◄ 20 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye

the colour of the
iris varies among
individuals

Why does the pupil always appear black in
colour?
Aristo 16.1 16.2 16.3 16.4 ◄ 21 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Inner layer
retina
(視網膜)

contains photoreceptors (light-sensitive cells)
(感光細胞): rod cells (視桿細胞) and cone cells
(視錐細胞) to detect light
Aristo 16.1 16.2 16.3 16.4 ◄ 22 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
three layers of wall of the eyeball :
Inner layer

yellow spot
(黃點)
blind spot
(盲點)

Aristo 16.1 16.2 16.3 16.4 ◄ 23 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye

yellow spot blind spot
contains the region
cone cells where the optic
only nerve (視神經)
leaves the eye
contains no
photoreceptors

Aristo 16.1 16.2 16.3 16.4 ◄ 24 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
divided into two chambers

anterior chamber

posterior chamber

Aristo 16.1 16.2 16.3 16.4 ◄ 25 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
divided into two chambers

anterior chamber filled with aqueous humour
(水狀液) :
a clear, watery solution
supplies nutrients and
oxygen to the cornea and
the lens

Aristo 16.1 16.2 16.3 16.4 ◄ 26 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
divided into two chambers

filled with vitreous humour (玻璃狀液) which
is a clear jelly-like fluid

posterior chamber

Aristo 16.1 16.2 16.3 16.4 ◄ 27 ►
16.2 Human eyes as the sense organs for detecting light

The internal structure of the human eye
divided into two chambers

anterior chamber the fluids inside both
chambers can…
maintain the shape
of the eyeball
refract and focus
light
posterior chamber

Aristo 16.1 16.2 16.3 16.4 ◄ 28 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.1
Examination of a human eye model

Procedure
Examine a human eye model.
Identify the various structures of
the eye.

Aristo 16.1 16.2 16.3 16.4 ◄ 29 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.1

optic nerve cornea

eye muscle sclera

Aristo 16.1 16.2 16.3 16.4 ◄ 30 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.1

iris

pupil

Aristo 16.1 16.2 16.3 16.4 ◄ 31 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.1

vitreous lens
humour

Aristo 16.1 16.2 16.3 16.4 ◄ 32 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.1

retina

Aristo 16.1 16.2 16.3 16.4 ◄ 33 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

Dissection and examination of an
ox eye
In this practical, you will
dissect an ox eye. An ox eye
and the human eye have a
similar overall structure.

Aristo 16.1 16.2 16.3 16.4 ◄ 34 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

Dissection and examination of an
ox eye
By examining the anatomy
of an ox eye, you can gain a
better understanding of the
structure and function of
different parts of the eye.

Aristo 16.1 16.2 16.3 16.4 ◄ 35 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

Procedure
1. Place an ox eye on a dissecting board. Examine
the external structure of the eye. Locate and
identify the eye muscles, the eyelashes, the
eyelids (if still present), the sclera, the cornea
and the optic nerve.

Aristo 16.1 16.2 16.3 16.4 ◄ 36 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

2. Remove the eyelids, the fat and the eye
muscles around the eyeball with scissors.
Be careful not to cut away the optic nerve.

Wear a mask and disposable gloves.
Scissors and scalpels are sharp. Handle
them with care.

Aristo 16.1 16.2 16.3 16.4 ◄ 37 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

3. Make a small cut at the
centre of the cornea with scalpel
a scalpel. Then cut
through the cornea twice
diagonally with scissors.
Note the liquid that flows cornea
out when the cornea is
cut open. This is the
aqueous humour.

Aristo 16.1 16.2 16.3 16.4 ◄ 38 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

4. Spread out the four flaps of the cornea.
Examine the iris and the pupil.

pupil cornea

iris

Aristo 16.1 16.2 16.3 16.4 ◄ 39 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

5. Cut through the iris and
into the sclera to about
half-way around the wall
of the eye.

pupil
iris
sclera

Aristo 16.1 16.2 16.3 16.4 ◄ 40 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

5. Locate and identify the lens, the suspensory
ligaments, the ciliary body and the vitreous
humour.

lens suspensory
ligament
vitreous
humour ciliary body
iris

Aristo 16.1 16.2 16.3 16.4 ◄ 41 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

Is it easy to cut through the sclera? Describe
the texture of the sclera.
No, it is not easy to cut through the sclera.
The sclera is tough and strong.

Aristo 16.1 16.2 16.3 16.4 ◄ 42 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

Compare the viscosity of the aqueous
humour and the vitreous humour.
The vitreous humour is more viscous than
the aqueous humour./ The aqueous humour
is more watery while the vitreous humour is
more jelly-like.

Aristo 16.1 16.2 16.3 16.4 ◄ 43 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

6. Pick up the lens carefully with forceps and
avoid making any scratches on the lens. Put it
on a piece of newspaper with text printed on
it. Observe what the text looks like through
the lens. Squeeze the lens gently with your
fingers and feel the texture of the lens.

Aristo 16.1 16.2 16.3 16.4 ◄ 44 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

What is the shape of the lens?
The lens is biconvex in shape.

What do you observe when you look at the
printed text through the lens?

The printed text of the newspapers looks
bigger through the lens. / The printed text is
magnified.

Aristo 16.1 16.2 16.3 16.4 ◄ 45 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

What is the texture of the lens when you
squeeze it?
The lens is elastic.

Aristo 16.1 16.2 16.3 16.4 ◄ 46 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

7. Empty out the jelly-like vitreous humour from
the eyeball. Examine the retina and locate the
blind spot.
blind spot

Aristo 16.1 16.2 16.3 16.4 ◄ 47 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

How can you locate the blind spot?
The blind spot is located on the retina where
the optical nerve leaves the eye.

Aristo 16.1 16.2 16.3 16.4 ◄ 48 ►
16.2 Human eyes as the sense organs for detecting light

Practical 16.2 Video

8. Lift up the retina with forceps and examine
the choroid underneath.

After the practical,
dispose of the ox eye, the mask and the gloves as
directed.
collect the apparatus used for central sterilization
by the technician.
wash your hands thoroughly with soap and water.

Aristo 16.1 16.2 16.3 16.4 ◄ 49 ►
16.2 Human eyes as the sense organs for detecting light

How do we see?
light rays from the object are refracted by…

light ray from an object ❸ lens
❹ vitreous
❶ cornea humour

❷ aqueous humour

Aristo 16.1 16.2 16.3 16.4 ◄ 50 ►
16.2 Human eyes as the sense organs for detecting light

How do we see?
focused on the retina to form an image

retina

Aristo 16.1 16.2 16.3 16.4 ◄ 51 ►
16.2 Human eyes as the sense organs for detecting light

How do we see?

object image on
the retina

The image formed on the retina is a real,
vertically and laterally inverted image that is
smaller than the object.
Aristo 16.1 16.2 16.3 16.4 ◄ 52 ►
16.2 Human eyes as the sense organs for detecting light

How do we see?
light rays focused onto the retina
stimulate the photoreceptors
generate and send
nerve impulses along
the optic nerve

to the visual centre
of the brain
Aristo 16.1 16.2 16.3 16.4 ◄ 53 ►
16.2 Human eyes as the sense organs for detecting light

How do we see?
the brain interprets the nerve impulses and
produces vision

upright image

Aristo 16.1 16.2 16.3 16.4 ◄ 54 ►
16.2 Human eyes as the sense organs for detecting light

What if the image is formed on the blind spot?
layer of
layers of neurones
nerve fibres to
image formed on the blind spot is photoreceptors
not visible
optic nerve
cone cell
rod cell
no nerve impulses are
choroid
blind generated
sclera
spot
X
to brain
No photoreceptors optic nerve blood vessels

Aristo 16.1 16.2 16.3 16.4 ◄ 55 ►
16.2 Human eyes as the sense organs for detecting light

Activity 16.1 Mini Lab

Finding the blind spot
There is a blind spot in each eye. Try this activity
to find the blind spot in your right eye.

Aristo 16.1 16.2 16.3 16.4 ◄ 56 ►
16.2 Human eyes as the sense organs for detecting light

Activity 16.1 Mini Lab

Hold your book at arm’s length. Close your left eye.
Focus on the cross with your right eye and slowly
move the book towards yourself. When the image
of the dot falls on the blind spot, you will not see it.

Aristo 16.1 16.2 16.3 16.4 ◄ 57 ►
16.2 Human eyes as the sense organs for detecting light

✗ No image is formed on the blind spot.

✓ An image is formed wherever incoming
light rays meet on the retina, so it can be
formed on the blind spot. However,
images formed on the blind spot is not
visible as there are no photoreceptors to
detect light.

Aristo 16.1 16.2 16.3 16.4 ◄ 58 ►
16.2 Human eyes as the sense organs for detecting light

1. Light rays that enter the eye are refracted by
the cornea , the aqueous humour, the
lens and the vitreous humour and focused
retina
on the.

Aristo 16.1 16.2 16.3 16.4 ◄ 59 ►
16.2 Human eyes as the sense organs for detecting light

2. Photoreceptors detect light falling on them and
send nerve impulses along the optic nerve
to the visual centre of the brain.
brain
3. The interprets the nerve impulses and
vision
produces.

Aristo 16.1 16.2 16.3 16.4 ◄ 60 ►
16.2 Human eyes as the sense organs for detecting light

Directions: Questions 1 and 2 refer to the diagram
below, which shows a section of the human eye.

1 4
2

3

Aristo 16.1 16.2 16.3 16.4 ◄ 61 ►
16.2 Human eyes as the sense organs for detecting light

1. Refraction of light occurs at surface(s)
A. 1.
B. 1 and 3.
C. 2 and 3.
D. 1, 2 and 3.

C
Aristo 16.1 16.2 16.3 16.4 ◄ 62 ►
16.2 Human eyes as the sense organs for detecting light

2. Which of the following is/are the function(s) of
structure 4?
(1) to supply nutrients to the eyeball
(2) to generate nerve impulses
(3) to reduce reflection of light within the eye
A. (1) only B. (1) and (3) only
C. (2) and (3) only D. (1), (2) and (3)

B
Aristo 16.1 16.2 16.3 16.4 ◄ 63 ►
16.2 Human eyes as the sense organs for detecting light

What are rod cells and cone cells?

rod cell

cone cell

Aristo 16.1 16.2 16.3 16.4 ◄ 64 ►
16.2 Human eyes as the sense organs for detecting light

Comparison between rod cells and cone cells

Rod cells Cone cells
Shape rod-shaped cone-shaped
Number more fewer
Distribution evenly distributed most concentrated
across the retina, at the yellow spot
except at the yellow and none at the
spot and blind spot blind spot
Aristo 16.1 16.2 16.3 16.4 ◄ 65 ►
16.2 Human eyes as the sense organs for detecting light

Comparison between rod cells and cone cells

Rod cells Cone cells
Sensitivity more sensitive less sensitive
(presence of visual
purple (視紫))
Stimulation by low light intensities by high light
(work well under dim intensities
light) (work well under
bright light)
Function black and white vision colour vision

Aristo 16.1 16.2 16.3 16.4 ◄ 66 ►
16.2 Human eyes as the sense organs for detecting light

Types of cone cells
Blue Green Red
cones cones cones
100
Sensitivity (percentage of light

Each of the three types
75 of cone cells contains a
different photosensitive
absorbed)

50
pigment, which absorbs
25
light of different
wavelengths,
0 corresponding roughly
380 450 500 550 600 650 700 750
to red, green and blue
light.
Wavelength of light (nm)

Aristo 16.1 16.2 16.3 16.4 ◄ 67 ►
16.2 Human eyes as the sense organs for detecting light

Types of cone cells
the colours we see depend on the relative
stimulation of the three types of cone cells
Red Green Blue Colour we
cone cells cone cells cone cells see
✔ red
✔ green
✔ blue
✔ ✔ yellow

Aristo 16.1 16.2 16.3 16.4 ◄ 68 ►
16.2 Human eyes as the sense organs for detecting light

Types of cone cells
the colours we see depend on the relative
stimulation of the three types of cone cells
Red Green Blue Colour we
cone cells cone cells cone cells see
✔ ✔ cyan
✔ ✔ magenta
✔ ✔ ✔ white
black

Aristo 16.1 16.2 16.3 16.4 ◄ 69 ►
16.2 Human eyes as the sense organs for detecting light

1. Rod cells can function in dim light and are
responsible for black and white vision.

2. Cone cells function well in bright light and are
colour
responsible for vision.

Aristo 16.1 16.2 16.3 16.4 ◄ 70 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
Figure 1 shows a horizontal section of the left eye.

side of the head centre of the head

80° 80°

60° 60°

40° Y 40°
20°
20°
X
Figure 1

Aristo 16.1 16.2 16.3 16.4 ◄ 71 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
Figure 2 shows the densities of the two types of
photoreceptors (rod cells and cone cells) in the
X
retina.
160,000
Number of photoreceptors

rod cells
120,000
per mm2

80,000

40,000 cone cells

0
80° 60° 40° 20° 0° 20° 40° 60° 80° Figure 2
Y
Aristo 16.1 16.2 16.3 16.4 ◄ 72 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
Use the information from Figures 1 and 2 to explain
the following:
(a) A person cannot see an object if its image falls
on area X. (2 marks)
Since there are no photoreceptors in area X, (1)
no nerve impulses are generated to stimulate
the visual centre of the brain. (1)
Therefore, the image falling on area X cannot be
seen.
Aristo 16.1 16.2 16.3 16.4 ◄ 73 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
Use the information from Figures 1 and 2 to explain
the following:
(a) A person cannot see an object if its image falls
on area X. (2 marks)

No marks can be scored by simply stating
that ‘X is the blind spot’ without reference
to the distribution of photoreceptors.

Aristo 16.1 16.2 16.3 16.4 ◄ 74 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
(b) It is easier to see a faint star if you look slightly
to the side rather than looking directly at it.
(4 marks)
When looking slightly to the side of the star, its
image falls on the periphery of the retina which
has a higher density of rod cells than the central
area. (1)
Rod cells are stimulated by dim light to generate
nerve impulses, so the star can be seen. (1)
Aristo 16.1 16.2 16.3 16.4 ◄ 75 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
(b) It is easier to see a faint star if you look slightly
to the side rather than looking directly at it.
(4 marks)
When looking directly at the star, its image falls
on Y where there are only cone cells, no rod
cells. (1)
The light from the faint star is too weak to
stimulate cone cells. (1)

Aristo 16.1 16.2 16.3 16.4 ◄ 76 ►
16.2 Human eyes as the sense organs for detecting light

Worked example 16.1
(b) It is easier to see a faint star if you look slightly
to the side rather than looking directly at it.
(4 marks)

Rod cells are much more sensitive to light
than cone cells, and can respond to lower
light intensities.

Aristo 16.1 16.2 16.3 16.4 ◄ 77 ►
16.2 Human eyes as the sense organs for detecting light

How to control the amount of light entering
the eye
1. In dim light
Side view Front view
radial muscles contract

iris
pupil dilates

circular muscles relax

Aristo 16.1 16.2 16.3 16.4 ◄ 78 ►
16.2 Human eyes as the sense organs for detecting light

How to control the amount of light entering
the eye
1. In dim light
Side view

stimulation of the
photoreceptors to
see in dim light

more light enter the eye

Aristo 16.1 16.2 16.3 16.4 ◄ 79 ►
16.2 Human eyes as the sense organs for detecting light

How to control the amount of light entering
the eye
2. In bright light
Side view Front view
radial muscles relax

iris

pupil constricts
circular muscles contract

Aristo 16.1 16.2 16.3 16.4 ◄ 80 ►
16.2 Human eyes as the sense organs for detecting light

How to control the amount of light entering
the eye
2. In bright light
Side view

prevents damage to
the photoreceptors

reduce amount of light enter the eye
Aristo 16.1 16.2 16.3 16.4 ◄ 81 ►
16.2 Human eyes as the sense organs for detecting light

✗ When bright light shines into the eye, the
pupil contracts.
✓ The pupil is a hole and cannot contract. It
can only be constricted or dilated by the
iris muscles.

Aristo 16.1 16.2 16.3 16.4 ◄ 82 ►
16.2 Human eyes as the sense organs for detecting light

1. The circular muscles and the radial muscles of
the iris can change the size of the pupil ,
thereby controlling the amount of light entering
the eye.
contract
2. In dim light, the radialrelax
muscles and
dilates
the circular muscles. The pupil
to increase the amount of light entering the eye.
Aristo 16.1 16.2 16.3 16.4 ◄ 83 ►
16.2 Human eyes as the sense organs for detecting light

3. In bright light, the circular muscles contract
and the radical muscles relax. The pupil
constricts
to reduce the amount of light entering the eye.

Aristo 16.1 16.2 16.3 16.4 ◄ 84 ►
16.2 Human eyes as the sense organs for detecting light

The graph below shows the changes in the
diameter of the pupil of a person’s eye during a
period of 30 seconds.

pupil diameter

X

0 10 20 30
time (s)

Aristo 16.1 16.2 16.3 16.4 ◄ 85 ►
16.2 Human eyes as the sense organs for detecting light

Which of the following combinations correctly
states the change in light intensity and the type of
iris muscles that begins to contract at X?
Light intensity Iris muscles contracting
A. increases circular muscles
B. increases radical muscles
C. decreases circular muscles
D. decreases radical muscles
D
Aristo 16.1 16.2 16.3 16.4 ◄ 86 ►
16.2 Human eyes as the sense organs for detecting light

What is eye accommodation?

near require
object more
refraction

divergent light rays

distant object
require
less
refraction
parallel light rays
Aristo 16.1 16.2 16.3 16.4 ◄ 87 ►
16.2 Human eyes as the sense organs for detecting light

What is eye accommodation?
adjust the amount of refraction require
of light to focus light rays on the more
retina refraction
eye accommodation (視覺調節)

by changing the require
curvature of the elastic less
lens of the eye refraction

Aristo 16.1 16.2 16.3 16.4 ◄ 88 ►
16.2 Human eyes as the sense organs for detecting light

How to focus on a near object
1 2
circular ciliary tension in suspensory
muscles contract ligaments decreases

4
light rays
light rays from
focused on
a near object
the retina

3
lens becomes thicker due to its
elasticity and refracts light more
Aristo 16.1 16.2 16.3 16.4 ◄ 89 ►
16.2 Human eyes as the sense organs for detecting light

How to focus on a distant object
1 2
circular ciliary tension in suspensory
muscles relax ligaments increases

4
light rays from light rays
a distant object focused on
the retina

3
lens becomes thinner shape
and refracts light less
Aristo 16.1 16.2 16.3 16.4 ◄ 90 ►
16.2 Human eyes as the sense organs for detecting light

1. Eye accommodation refers to changing the
shape of the lens to focus on objects at
different distances.

Aristo 16.1 16.2 16.3 16.4 ◄ 91 ►
16.2 Human eyes as the sense organs for detecting light

2. When focusing on a near object, the circular
ciliary muscles contract ; the tension in the
suspensory ligaments decreases ; the lens
more
becomes thicker ( convex) and light is
refracted more.

Aristo 16.1 16.2 16.3 16.4 ◄ 92 ►
16.2 Human eyes as the sense organs for detecting light

3. When focusing on a distant object, the circular
ciliary muscles relax ; the tension of the
suspensory ligaments increases ; the lens
less
become thinner ( convex) and light is
refracted less.

Aristo 16.1 16.2 16.3 16.4 ◄ 93 ►
16.2 Human eyes as the sense organs for detecting light

HKDSEE Biology 2015 Paper 1 Section A Q27
(Refer to p.16-19)

C
Aristo 16.1 16.2 16.3 16.4 ◄ 94 ►
16.2 Human eyes as the sense organs for detecting light

Eye defects

short sight (近視)

long sight (遠視)

colour blindness (色盲)

Aristo 16.1 16.2 16.3 16.4 ◄ 95 ►
16.2 Human eyes as the sense organs for detecting light

What is short sight and its correction?
see near objects more clearly
than distant objects

causes of short sight:
eyeball is too long
lens is too thick

Aristo 16.1 16.2 16.3 16.4 ◄ 96 ►
16.2 Human eyes as the sense organs for detecting light

What is short sight and its correction?
Focusing on a distant object
light rays from
a distant object

light rays focused in
Blurred image front of the retina

Aristo 16.1 16.2 16.3 16.4 ◄ 97 ►
16.2 Human eyes as the sense organs for detecting light

What is short sight and its correction?
Correction by wearing a concave lens
light rays from a distant object
diverged by a concave lens

concave lens
light rays focused
on the retina

Aristo 16.1 16.2 16.3 16.4 ◄ 98 ►
16.2 Human eyes as the sense organs for detecting light

What is short sight and its correction?

People with severe short sight have a
higher risk for retinal detachment.
This happens as the eyeball continues
to lengthen, pulling the retina away
from the choroid.

Aristo 16.1 16.2 16.3 16.4 ◄ 99 ►
16.2 Human eyes as the sense organs for detecting light

What is long sight and its correction?
see distant objects more clearly
than near objects
causes of long sight:
eyeball is too short
lens is too thin

Aristo 16.1 16.2 16.3 16.4 ◄ 100 ►
16.2 Human eyes as the sense organs for detecting light

What is long sight and its correction?
Focusing on a near object
light rays from
a near object
light rays
focused
behind the
retina

Aristo 16.1 16.2 16.3 16.4 ◄ 101 ►
16.2 Human eyes as the sense organs for detecting light

What is long sight and its correction?
Correction by wearing a convex lens
light rays from a near
object converged by
a convex lens
light rays
focused on
the retina

convex lens

Aristo 16.1 16.2 16.3 16.4 ◄ 102 ►
16.2 Human eyes as the sense organs for detecting light

What is long sight and its correction?

Note the following when drawing ray diagrams:
Use solid straight lines to present the light rays that
enter the eyes and reach the retina. Light rays behind
the retina should be drawn with dotted lines until they
intersect.
Light rays from a distant object should be parallel and
the object should not be drawn.
Light rays from a near object should be diverging from a
single point.
Arrowheads should be added to the light rays to
indicate the direction in which the light is travelling.
Aristo 16.1 16.2 16.3 16.4 ◄ 103 ►
16.2 Human eyes as the sense organs for detecting light

What is colour blindness?
inability to distinguish some or all colours
due to the poor functioning or a deficiency of
one or more types of cone cells
an inherited eye defect
no cure

Aristo 16.1 16.2 16.3 16.4 ◄ 104 ►
16.2 Human eyes as the sense organs for detecting light

What is colour blindness?
e.g. red-green colour blindness
cannot distinguish red and green
poor functioning or a deficiency of red or green
cone cells
normal colour vision red-green colour blindness

Aristo 16.1 16.2 16.3 16.4 ◄ 105 ►
16.2 Human eyes as the sense organs for detecting light

1. In short sight, the eyeball is too long or the
lens is too thick , resulting in the image of
distant objects being focused in front of
the retina. It can be corrected by wearing
concave
lenses.

Aristo 16.1 16.2 16.3 16.4 ◄ 106 ►
16.2 Human eyes as the sense organs for detecting light

2. In long sight, the eyeball is too short or the
lens is too thin , resulting in the image of
near objects being focused behind the retina.
convex
It can be corrected by wearing lenses.

Aristo 16.1 16.2 16.3 16.4 ◄ 107 ►
16.2 Human eyes as the sense organs for detecting light

3. In colour blindness, one or more of the three
types of cone cells function poorly or are
deficient. There is no cure for colour

blindness.

Aristo 16.1 16.2 16.3 16.4 ◄ 108 ►
16.2 Human eyes as the sense organs for detecting light

A person suffers from colour blindness and is
unable to focus on distant objects. Which of the
following can explain his conditions?
A. deficiency of visual purple; lens too thick
B. deficiency of visual purple; eyeball too short
C. deficiency of cone cells; lens too thin
D. deficiency of cone cells; eyeball too long
C
Aristo 16.1 16.2 16.3 16.4 ◄ 109 ►
16.3 Human ears as the sense organs for detecting sound

The human ears
sense organs for detecting sound

Aristo 16.1 16.2 16.3 16.4 ◄ 1 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the human ear?
auditory canal ear bones semicircular auditory
canals nerve
pinna

cochlea
oval window
round window
ear drum Eustachian tube

outer ear middle ear inner ear
(外耳) (中耳) (內耳)
Aristo 16.1 16.2 16.3 16.4 ◄ 2 ►
16.3 Human ears as the sense organs for detecting sound

Practical 16.3
Examination of a human ear model

Procedure
Examine a human ear
model. Identify the various
structures of the ear.

Aristo 16.1 16.2 16.3 16.4 ◄ 3 ►
16.3 Human ears as the sense organs for detecting sound

Practical 16.3

eustachian
tube pinna

auditory
canal

ear drum
Aristo 16.1 16.2 16.3 16.4 ◄ 4 ►
16.3 Human ears as the sense organs for detecting sound

Practical 16.3
auditory semicirular
nerve canals

ear bones
cochlea
Aristo 16.1 16.2 16.3 16.4 ◄ 5 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the outer ear?

pinna a flap of elastic
(耳殼) cartilage covered
with skin
collects sound
waves

Aristo 16.1 16.2 16.3 16.4 ◄ 6 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the outer ear?
auditory canal (聽道)
a passageway for
sound from the pinna
to the eardrum

Aristo 16.1 16.2 16.3 16.4 ◄ 7 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the outer ear?

thin, elastic
membrane
separates the outer
ear from the middle
ear
converts sound
eardrum waves into
(耳膜) mechanical
vibrations

Aristo 16.1 16.2 16.3 16.4 ◄ 8 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the middle ear?
an air-filled cavity
ear bones (聽小骨)

three ear bones
amplify and transmit the
vibrations from the eardrum to
the oval window (卵圓窗)
separating the middle ear from
middle the inner ear
ear
Aristo 16.1 16.2 16.3 16.4 ◄ 9 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the middle ear?

flexible membrane
separating the
middle ear from the
oval window inner ear
transmits vibrations
from the ear bones
to the inner ear

middle
ear
Aristo 16.1 16.2 16.3 16.4 ◄ 10 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the middle ear?

flexible membrane
allow the release of
pressure in the
cochlea
round window
(圓窗)

middle
ear
Aristo 16.1 16.2 16.3 16.4 ◄ 11 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the middle ear?

connects the middle
ear to the pharynx
equalizes the air
pressure on both
sides of the eardrum
Eustachian tube
(耳咽管)
middle
ear
Aristo 16.1 16.2 16.3 16.4 ◄ 12 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the inner ear?
semicircular canals (半規管)

fluid-filled tubes
detect head movements and
help us have a sense of balance
inner ear

Aristo 16.1 16.2 16.3 16.4 ◄ 13 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the inner ear?

auditory nerve (聽神經)

transmits nerve impulses to the
auditory centre of the brain

inner ear

Aristo 16.1 16.2 16.3 16.4 ◄ 14 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the inner ear?
semicircular auditory
canals nerve

a tube coiled into a
spiral shape
cochlea separated by
(耳蝸) membranes into
three liquid-filled
canals
for hearing
inner ear

Aristo 16.1 16.2 16.3 16.4 ◄ 15 ►
16.3 Human ears as the sense organs for detecting sound

Cochlea
upper canal filled with perilymph (外淋巴)
central canal filled with
endolymph (內淋巴)

lower canal filled
with perilymph
auditory nerve
Aristo 16.1 16.2 16.3 16.4 ◄ 16 ►
16.3 Human ears as the sense organs for detecting sound

Cochlea
the movements of
the endolymph
cause the hairs of membrane
the sensory hair hair
cells (感覺毛細胞)
to bend

sensory hair cell

Aristo 16.1 16.2 16.3 16.4 ◄ 17 ►
16.3 Human ears as the sense organs for detecting sound

What is the structure of the human ear?
the sensory hair cells
are stimulated
send nerve impulses membrane
along the auditory hair
nerve to the auditory
centre of the brain

to auditory nerve sensory hair cell

Aristo 16.1 16.2 16.3 16.4 ◄ 18 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?
1

1
the pinna collects sound waves into the
auditory canal

Aristo 16.1 16.2 16.3 16.4 ◄ 19 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?
2

2
the sound waves cause the eardrum to vibrate

Aristo 16.1 16.2 16.3 16.4 ◄ 20 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?
3

3
the ear bones amplify and transmit the
vibrations from the eardrum to the oval
window
Aristo 16.1 16.2 16.3 16.4 ◄ 21 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?
4

4
the oval window vibrates and causes wave
movements of the perilymph in the upper
canal of the cochlea
Aristo 16.1 16.2 16.3 16.4 ◄ 22 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?

5

5
the wave movements are transmitted to the
endolymph in the central canal

Aristo 16.1 16.2 16.3 16.4 ◄ 23 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?

6

6
sensory hair cells are stimulated to generate
and send nerve impulses

Aristo 16.1 16.2 16.3 16.4 ◄ 24 ►
16.3 Human ears as the sense organs for detecting sound

How do we hear?
7

7
nerve impulses travel along the auditory nerve
to the auditory centre of the brain to produce
the sensation of hearing
Aristo 16.1 16.2 16.3 16.4 ◄ 25 ►
16.3 Human ears as the sense organs for detecting sound

1. The pinna of the outer ear collects and directs
sound waves along the auditory canal to the
eardrum, which converts sound waves to
mechanical vibrations.
amplify
2. In the middle
transmit ear, the ear bones and
the vibrations from the eardrum to
oval window
the.
Aristo 16.1 16.2 16.3 16.4 ◄ 26 ►
16.3 Human ears as the sense organs for detecting sound

3. Vibrations of the oval window cause wave
movement of the liquids in the cochlea.

4. Movement of the endolymph cause the hairs of
sensory hair cells bend
the in the cochlea to ;
sensory hair cells
nerve impulses are stimulated to send
auditory nerve
along the to
the brain.
Aristo 16.1 16.2 16.3 16.4 ◄ 27 ►
16.3 Human ears as the sense organs for detecting sound

5. Nerve impulses are interpreted by the brain to
produce the sensation of hearing.

Aristo 16.1 16.2 16.3 16.4 ◄ 28 ►
16.3 Human ears as the sense organs for detecting sound

HKDSEE Biology 2013 Paper 1 Section A Q29
(Refer to p.16-29)

C
Aristo 16.1 16.2 16.3 16.4 ◄ 29 ►
 16. Phototropic responses in plants
4

Irritability in plants
plants can detect stimuli
(e.g. light and water)
respond by growing
certain parts of their body
(e.g. shoots and roots)

Tropism (向性)

Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

Irritability in plants
grows towards the
stimulus

positive response

grows away from the
stimulus

negative response

Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

How do plants response to light?

Phototropism
(向光性)

the directional growth movement of a
plant part in response to unilateral light
(i.e. light coming from one direction only)
Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

Practical 16.4 Vide
o
Investigation of the phototropic
responses of shoots and roots
Procedure. Set up the apparatus as shown below.

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Practical 16.4 Vide
o
light-
proof box
shoot light light
cardboard
root light light
culture
solution rotating
stand clinostat
Set-up A Set-up B

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Practical 16.4 Vide
o
Why are slits made on one side of the light-
proof boxes?
To provide unilateral light to the seedlings
inside the boxes.

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Practical 16.4 Vide
o
Which set-up is the control? Explain its use
in this investigation.
Set-up B is the control. The rotation of
clinostat cancels out the effect of unilateral
light on the shoots and roots of the seedlings.
This is to show that any changes in the
appearance of the seedlings in the
experimental set-up (set-up A) are due to
unilateral light.
Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

Practical 16.4 Vide
o
1. Observe and record how the seedlings have
grown in the two set-ups after two days.

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Practical 16.4 Vide
o
Results

Appearance of the seedlings
Set-up
Shoots Roots
A bend towards light bend away from light
grow vertically grow vertically
B upwards downwards

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Practical 16.4 Vide
o
Discussion
In set-up A, the seedlings are subjected to
unilateral light. The shoots grow towards the
light source, and the roots grow away from it.
In set-up B, the effect of unilateral light is
cancelled out by the rotation of the clinostat, and
so the seedlings are equally illuminated on all
sides. The shoots grow vertically upwards, and
the roots grow vertically downwards.
Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

How do shoots response to light?
positively phototropic
growing towards unilateral
light
to obtain the maximum
amount of light for
photosynthesis

Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

How do roots response to light?
negatively phototropic
growing away from
unilateral light
ensures the roots grow
downwards into the soil
for anchorage

Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

Phototropism investigation
a coleoptile is a protective sheath that covers
the first leaf of a monocotyledonous seedling

coleoptile
coleoptile first leaf
first leaf

grain
fast-growing
easy to handle
have simple structure for observation

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
Charles Darwin’s experiment

coleoptile with opaque bending growth in the
tip removed coverings region below the tip

ligh
t

a b c d a b c d

start results
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
unilateral light was detected
by the tip of the coleoptiles

ligh
t

a b c d a b c d

start results
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
bending growth occurs in
the region below the tip

ligh
t

a b c d a b c d

start results
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation

some kind of signal must be transmitted from
the tip to the lower part of the coleoptile

ligh
t

a b c d a b c d

start results
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
Boysen-Jensen’s experiment 1
a tip placed back on agar block b mica plate inserted
below the tip

ligh ligh
t t
agar mica
block plate

start start
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation

Chemicals can diffuse through the
agar block but not the mica plate.

ligh ligh
t t
agar mica
block plate

start start
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
grew and bent towards the light no change
a tip placed back on agar block b mica plate inserted
below the tip

ligh ligh
t t
agar mica
block plate
chemical signal is transmitted from the tip
to the lower
start result part of the coleoptiles
start result
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
Boysen-Jensen’s experiment 2
a mica plate inserted on b mica plate inserted
illuminated side on shaded side
ligh ligh
t t

start produced
the chemical result start result
by the tip passes down
the shaded side of the coleoptile
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
Frits Went ’s experiment 1

In darkness
tip removed
tip allowed to stand on agar
block for several hours

agar block

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
agar block
Conclusion 1:
the agar block contained
the chemical produced by
the tip of the coleoptile

Conclusion 2:
this chemical stimulated
start result growth as it passed down
a agar block placed on the decapitated coleoptile
decapitated coleoptile
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
agar block
Conclusion 3:
higher concentration of
the growth-promoting
chemical on the one side
causes bending on the
other side

start result
b agar block placed on one side
of decapitated coleoptile
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
Frits Went ’s experiment 2

X X Y Y

ligh
t X Y
start result start result
In darkness
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

Phototropism investigation
shaded side had unilateral light had caused an
a higher uneven distribution of the
concentration chemical
X X Y Y
of the chemical

ligh
t X Y
start result start result
named as auxin (⽣長素) In darkness
Aristo 16.1 16.2 16.3 16.4 0
 16. Phototropic responses in plants
4

What are auxins?
a group of plant hormones
produced in the apical meristem at the tip of
shoots and roots
are then transported to the regions of
elongation
stimulate the cells to elongate
promote growth

Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

What are the effects of auxins on shoots and
roots?
200
promote root growth but insufficient for shoot growth
Percentage 150 shoots
stimulation of
growth (%) 100
roots
50

0
Percentage
inhibition of 50
growth (%)
100
10- 10- 10- 10- 10- 10- 1 10 102 103 104
6 5 Concentration
4 3 of auxins
2 1(parts per million, ppm)
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

What are the effects of auxins on shoots and
roots?
200

Percentage 150 promote both root and shoot growth
shoots
stimulation of
growth (%) 100
roots
50

0
Percentage
inhibition of 50
growth (%)
100
10- 10- 10- 10- 10- 10- 1 10 102 103 104
6 5 Concentration
4 3 of auxins
2 1(parts per million, ppm)
Aristo 16.1 16.2 16.3 16.4 0
16. Phototropic responses in plants
4

What are the effects of auxins on shoots and
roots?
200

Percentage 150 shoots
stimulation of
growth (%) 100
inhibit root growth while
roots
promote shoot growth
50

0
Percentage
inhibition of 50
growth (%)
100
10- 10- 10- 10- 10- 10- 1 10 102 103 104
6 5 Concentration
4 3 of auxins
2 1(parts per million, ppm)
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16. Phototropic responses in plants
4

What are the effects of auxins on shoots and
roots?
200

Percentage 150 shoots
stimulation of
growth (%) 100 inhibit both shoot and root growth
roots
50

0
Percentage
inhibition of 50
growth (%)
100
10- 10- 10- 10- 10- 10- 1 10 102 103 104
6 5 Concentration
4 3 of auxins
2 1(parts per million, ppm)
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16. Phototropic responses in plants
4

What is the mechanism of phototropic
responses?
light from all directions

evenly the shoot
auxins distribution grows
shoot of auxins straight up

root
auxins the root
grows
auxins are produced in the straight
shoot tip and root tip down

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16. Phototropic responses in plants
4

What is the mechanism of phototropic
responses?
high auxin concentration stimulates shoot growth:
on the shaded side the shaded side grows faster
the shoot bends towards the light

auxins unilateral unilateral
light light
shoot

root
auxins
inhibits root growth:
auxins are produced in the the shaded side grows more slowly
shoot tip and root tip the root bends away from the light
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 16. Phototropic responses in plants
4. Phototropism is the directional growth
movement of a plant part in response to
unilateral light. Shoots are positively
phototropic while roots are negatively
phototropic.

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 16. Phototropic responses in plants
4. Phototropism is controlled by auxins. Auxins
are produced in the apical meristems at
shoot tips and root tips, and are transported to
the regions of elongation where they
affect growth.
3. High concentrations of auxins promote
shoot growthinhibit
but root growth.

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16. Phototropic responses in plants
4

1. HKDSEE Biology 2012 Paper 1 Section A Q30
(Refer to p.16-38)

C
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16. Phototropic responses in plants
4

2. HKDSEE Biology 2014 Paper 1 Section A Q36
(Refer to p.16-38)

C
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