Ecology (Bonnie's Note) PDF

Summary

These notes cover the fundamentals of ecology, the study of relationships between organisms and their environment. Topics include ecosystems, biotic and abiotic factors, energy flow, and nutrient cycling, providing a general introduction to the subject. The notes focus on definitions, key concepts, and examples within ecological frameworks.

Full Transcript

ECOLOGY
 to
Eure1 : Intro
Ecology

Ecology : The
study of the relationships of organisms and their environment.

1869
*
Ecology >
-
*

3
of homes
Oikos = Home the
study
trees
Logos study Ants
=
ex. on

Natural
History
Ecology VS.

out and finding organisms
going
·

·

systematic and quantitative (#)
·

the descriptive study' of
organisms in their wild habitats.
·
science that asks us

why things are the
way
#s
they are.
(using

Abiotic VS , Biotic

·
not alive (temp ·

Alive (Ants)

influenced influenced by disease , compet.
by env. ~
other
organisms through
·
moisture , nutrients , fire , toxin.

predation ,
disease , mutualism

·

conspecific or interspecific org ·

·
direct effects (predation]
· indirect effects (competition for resources

Read page 49.
Ecosystems :
Fundamental unit in
ecology
)
↳
include Abiotic /Biotic

↳) can be
large (biosphere
↳ small ) pitcher plant)
L toxins

3
would live animals.
in bottom
plant digest
↳
watere top

of increase in Biomass
↑ Rate
En of an ecosystem described by productivity (Energy dynamic
by D in nutrients (nitrogen fixation

by flow of energy

by flow of water

Ecology is a science

·
common features of ecological studies

>
- field-based research

-
sophistared took

Hypothesis testing
>
-

>
-
stat -

analysis
ex. noise
monotring

-
 Lecture 2
u

Environmental factors Features that affect ind. pop , communities landscapes etc.
organisms,
:
, ,

·
Biotic or Abiotic

natural
·
or
anthropogenic

affectI n such as
productivity decomp nutrient
cycling
·

, ,

factors
Limiting factor with lowest
availability relative to need
:

mineral nutrients are often a
limiting factor for ecosystem
productivity
·

ex.

phosphorus often limits lake
productivity
·
additional phosphorous
light
visible
Isolar Radiation)
weight product collected
-
:

of
organic matter by organic molecules.
1.

energy flows through ecosystem
· measured on dry weight basis
HonsOfdruweitn (Birds see ur light , unlike humans)
accumulation. Nutrients
2
cycle through ecosystem productivity
:
rate of energy fixation # biomass vital for
Autotrophs = self
feeding (plants Algae ,

the rate of Diomass

accumulation
photosynthesis sunlight : + 610 +
6H20 +
CH 200 +
602

&
,

(plants algea cynobacterial
, ,

1st law of -

thermodynamics Absorb solar radiation 102 +20 simple sugars +
oxygen
+ +

energy cannot be created or destroyed
-

Heterotrophs :
(Animals , fungil only live
by feeding off other
organisms
thermal ,a
disappate
input outprchemical
, ,

photosynthesis Also be released as.
heat (flow
through system)
·

↳ solar
↳ of solar
Delayed release energy
withinSeasons times oflotsofsolarenya
↑
2nd Law thermodynamics - reflected or
Absorbed ↳ varies with latitude.
* dissapated
by reradiation
Energy transformation % (reflected)
energy) (heat)
can occur ~
30 into space
(infrared
~
25 % absorbed /atmosphere)

spontaneously only under conditions ~ 45 % absorded (surface

in which
entropy of the universe.
4
Also evapotranspiration : crap from all surfaces.
·
↑
evaporation
from organisms page (53)
:
disorder transpiration liquid ~
gas
·.
ex in order for balloon to inflate , it needs energy endothermic
Absorbs energy
latent heat Centhalpy

Greehouse - H20 CH3 D4GG through
gasses CO2 , ,

Combustion , deforestation
4) Absorb dissapated infrared radiation
+
agriculture
and re-adidte it in all directions.
Energy Fixations in ecosystems.

3
·

provides thermal blanket (15c)
# 4 through years page5
Autotrophs-primary producers
·

photoautotrophs plants , Algea , (light self feeders) gross primary production (GPP
Cynobacteria
· :

> productivity in Diosphere
total amount of
-

= solar
energy
Global decomp. UpsChlorophyipmentscapturephotoAppear produced
warming > 4 productivity
4 drought
green
↳ Also
My
↑ chemoautotrophs : specialized bacteria (live in dark)
Anthrogenic increases in GG cause in tem
·

-) Chemosynthesis metabolism : energy from inorganic chemicals
sulphide minerals (
(oxidizing
RespirationAmtofchera
fish
·
Cod , Angel , snake blenny have shifted north. >
-
exothermic - CO2 +
Ho =
glucose
tabolism
-) ex Volcanic sea deep vents provide energy.

10 5.
-
0. 75)

Heterotrophs productivity of major biomes productive
habitat with ↓ environmental constraints
:

Net primary Production
a

* not all plants are autotrophs (warm numid climate ,
fertile soil).

Rainforest = most diverse ecosystem.

LDex ghostpipe-no chlorophyll.
Energy transfer :
·

At trophic level of
from ↓ NPP b ↓ nutrient
a
large part
availability
,

energy surrounding trees open oceans > <
-

L ·.

energy is lost at
respiration.
·
Reefs -P 4 NPP (like underwater Rainforest) ,

Energy& as you P trophic levels

Food chain feeding interactions
energy transfer
:
linear +.

·

only a part
of energy food used ·

earth can sustain 10 billion people but only
if
levels
·Herbarores Do energy
inoit
Biomagnification : Humans produce toxins we eate lower trophic
that do not occur naturally.
eX.
organochlorides ,
DDT , mercury
·
these enter food chains

Food Web All
feeding food chains
:
interactions
amoung
Lecture 4-Pnutrient
nu
↓
cycling
sub ·

necessary for
healthy physiogy of org.

factor limits growth Abiotic factors
principle limiting
·.

water
-
ex.
Phosphorus +
nitrogen often limit
productivity in

↳ result in
algedblooms I
L influx of nutrients macronutrients required
a : in
large quant. *
hemoglobin-Diron
Oxygen Hydrogen
,
CarbonBiological process
,

plants ↑ Carbon P Ca,
:S
--
AkA mineral nutrients , ,

Poxygen
(same for AA to live

humans) Phydrogen
↑
micronutrients :
required in small
quantities
↑ micronutrients 4 Fe , Mn , B ,2 ,
Cl ,
Na...

u lack of these ,
could lead to defencies

Toxicity long to toxic sub.
Hyper accumulation plants neutralize toxic sub
:
: essential nutrients become Tolerance :
exposure
toxic e levels
high
Icope with
leads to evolution of tolament org
, by collecting in vacuoles

ex nickel + copper-stunt growth extra nutr) metal
Mangroves salf tolerance. Mangroves.

ex > ex -n
hyperacs.
· - ·..

↳ depends on
organism. ex Plants develop tolerance to toxic metals
Bioremediation exploits.
·
·

to help collect pollutants
 Lecture 5
un

(one species) ex.
Cod.

Population ecology study
: of
population dynamics of species and how pop. interact with the.
environment

↳ How ?
quickly do pop ,

grow

↳ What factors limit ?
pop. growth

?
↳ How
many organisms
in an equilibrium pop.

·

pop. 41d for
short/long time

(like compound interst
population
growth

f
of conspecific
group
·

17
ind. that inhabit the
same ared.
log.

- - V

closed population * Exponential growth Logistic growth
·
isolated from other
open population
ind. D4
immigrate Bd
nothing stoodinwayofgot...
groups
·

,

·
pengiuns-p easier to study. and/or emigrate
(D) deaths (B) Births (1))
Field mice , Redfow , Moose , s h a r k
carrying capacity
· :.
·
max sus.
· humans 2
quickest growth
·

if B > D ;
pop 4
(1) (e) emigrants.
immigrants pop. size in a
given environment
·.

·

Doubling time
(N-P2N)
if B fight males in other.

-

groups to take place
> kills all cubs
-

Australian..
3
Othercloselyreptedspeciesism
while
female-way larger than male 1 sexual dimorphism) Female eat male
mating 1. Adult male
odour ,
recognizes
triggering aggression.
unrelated cubs by unfam.
-
produces renon
males achieve ↑ reproductivity when
cyclesreachsexual maturity
4..
2 3 as
yeard
they insert themselves into female

Foraging behaviour food choices linked with fitness takes female more time = more
to eat
sperm.
3 3 other panthra species (tigers leopards jaguars
·
:
, ,

are more solitary.

4.
will enter if
Females
longer
↑
selective + efficient estrus sooner no
have dependent cub.

and when visited them
ex. bees : rur flowers
they so
they
time for nectar to produce
give
Sexual selection

Enemies (Predation) :

forging canI predation -intersexual secondary
usually result in
sexual characters
sexual
:

dimorphism
hidden weapons that

intrasexual
consious about predators selection
selectio
· one sex lusually
Often tradeoff ·

comp. btw the females ,
discriminating
·

reproduction more important for succes
Survival.
same sex
cusually mates than ind

ex
squirrel eat sunflower easy access males) for access to females look for better suicidal copulation ↑ reproductive
: -.
man ·
success
can lead to aggression I
D
·

chestnut takes time
they'll weaponary ornamentation : Visual and
:
so rum wit
display
-.

phermone signals
Batemans principle
:variabilityinreproductia ·
reveals males condition
than females.
Enemies (Parasites) :
symbiotic relationship female picks what she likes
·

females contribute more materials of
egg · tails vibrants
·

I thrives the other ↓ fitness ·
females reproductive limit -

poffspring the can bear -

Dbigtail Ffly.

males >
-
Access to ferals

ex infected ants get eaten ,
birds eat ants , bird gets infected

brood parasite
·
:
lek-based
activ of other
mating system Animals
:
paratisize the parental species
gather to one.
spotto mate
·
use A host
social behaviour kin selection : NS favours
: AdvantoGroupinga genetic contribution
ex Great Green warlder Altrustic = Actor
disadvant compet , 4 infection to future
generations through
:

oses.

more mouths to feed. , recipient
those related to them. Gains
·

puts one
egg in different nest
helping
live in but ONLY Help others preed.
cusocial organisms
:
groups 2 paths : (1) reproduce yourself
Quicker to to help
grow-Hatch resources queen
·

ex · ants help bring -D Share 50 % genes w offspring
her reproduce. 12) help relative reproduce
>
-
Share 25 % genes woffspring
·
For this to occur
,
loss of fitness must outweight
come BACK to

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