Photosynthesis 1 - Photosynthetic Organisms PDF

Summary

This document provides an overview of photosynthesis, focusing on prokaryotic and eukaryotic autotrophs, the location of photosynthesis in higher order plants, the process of transpiration and the role of stomata. It also explores different plant pigments, light properties, and the effects of light on atoms. The document is suitable for secondary school-level learners.

Full Transcript

Prokaryotic Autotrophs
Examples includes cyanobacteria, which is a blue-green algae
Thrive on nitrogen and phosphate which can cause algal blooms
which discolour water and may be toxic to other species
Came into existence about 3.5 to 4 billion years ago and was first
living thing to produce oxygen
 Eukaryotic Autotrophs
Examples include
algae, plants, and
photosynthetic
protists
These are
organisms that have
organelles called
chloroplasts that
contain chlorophyll
Where is photosynthesis taking
place in higher order plants?
Leaves

Mostly in spongy and palisade mesophyll

Chloroplasts

Thylakoids

Chlorophyll molecules are the key
Leaves
 Transpiration
The loss of water from leaves
Pulls water up the plant from roots due to
water cohesion
Assists photosynthesis
Moves substances (water, minerals, etc) to leaves
where photosynthetic reactions occur
Evaporative cooling effect – prevents inhibition or

denaturation of photosynthetic enzymes
 Control of Stomata
Stomata are openings on surface of leaf
Allow for the movement of gases (CO2 and water
vapour)
Controlled by sizes of guard cell
 Control of Stomata

a) Light activates specific receptors in guard cell membranes
b) Results in stimulation of proton pumps that move protons out of
the cell
c) Creates electrochemical gradient that causes K+ ions to move into
cell
d) Water moves in by osmosis
 Chloroplast Structure

(Protein-rich
fluid)

(Attach grana)

(A stack of
thylakoids)
 Location of
Photosynthesis
Occurs in the stroma, and the thylakoid
membrane
The thylakoid membrane contains:
Light-gathering pigment molecules (chlorophyll)
Electron transport chains

Structure of thylakoid system greatly
increases surface area and photosynthesis
efficiency
Plant Pigments
Pigments are molecules that can absorb
certain wavelengths of light while reflecting
others

Chlorophylls are easily excited by light and
are the key to photosynthesis
 Properties of Light
Light (electromagnetic radiation) is a form of energy
that travels in the form of wave packets called photons

The amount of energy is inversely proportional to the
wavelength (λ)
E=1/λ

The visible part of the electromagnetic spectrum
ranges from 380 nm to 750 nm
Electromagnetic Spectrum
Effect of light on Atoms
Light energy when directed on
atoms can cause electrons to
go to higher energy levels.

Electrons at higher levels are
unstable and will fall back
down to their ground state 
energy (in the form of light)
given off as it falls
 Chlorophyll
Photosynthetic organisms contain the green-
coloured pigment chlorophyll

STRUCTURAL PARTS
Head - Porphyrin ring
Complex ring with carbon double bonds
Ring contains a Mg atom
Light excites electrons in the double bond orbitals

Tail – Phytol Chain
Hydrocarbon that helps to anchor and orient the
molecule in the thylakoid membrane

Chlorophyll a and b differ in the ‘R’ group
that is attached at the head
Chlorophyll
Chlorophyll a and b
Chlorophyll a – absorbs red light the best
Chlorophyl b – absorbs violet-blue light the
best

Many of the green wavelengths are NOT
absorbed and thus get reflected into our
eyes
 Prisms separate white light into different wavelengths
(colours).

Chlorophyll molecules absorb the red and blue ends of the
spectrum but reflect the yellow and green parts.
Caretenoid Pigments
Beta carotene - specialized at absorbing particular wavelengths and
reflect yellows red ranges

Xanthophylls – absorb yellows, reflect oranges
 Chlorophyll and accessory
pigments
Chlorophyll a is the only pigment that can
transfer the energy of light to the carbon fixation
reactions of photosynthesis – i.e. it’s electrons in
the porphyrin head move to higher energy levels
Chlorophyll b acts as an accessory pigment,
absorbing photons that chlorophyll a absorbs
poorly, or not at all
Carotenoids, xanthophylls and anthocyanins act
as accessory pigments
Absorbance spectra
Rate of oxygen production related to
wavelengths of light absorbed
Action Spectrum
What causes “Autumn Leaves”?
Synthesis of chlorophyll requires sunlight and
warm temperatures
Shortened daylight and cooler temperatures
prevent nutrients from reaching leaves 
chlorophyll production decreases

Other pigments in the
leaves will be left to
reflect other colours of
the spectrum

In some leaves,
concentration of sugars
will increase  forms
another pigment called
anthocyanin
 Anthocyanins
Absorb blue-green, blue, and green light  reflect red light
Not part of thylakoid membrane like other pigments are
 they are dissolved in sap
If the sap is more acidic then pigment appears bright red
If the sap is less acidic then pigment appears more purple