Birds Flashcards
Very diverse
size
plumage
Habitat
Mating systems - monogamy - polygyny - polyandry (male raises young) - Polygynandry - 2 male + female
Bills
Feathers
defining characteristic of birds
evolved from scales
light, soft, filamentous
Made from keratin - light - strong - waterproof
No. of feathers roughly constant for species
5 types - contour - down - semipume - filoplume - bristle
first 4 found in all
Contour feathers
Give smooth round shape - outer most feathers
Flight feathers - remiges - modified contour
Tail feathers - retrices - modified
First level of defence - sun/vegetation
Colours - pigments - melanins - made by bird (black/grey/tan) - carotenoids - diet (red/organge/yellow)
Bright male = good hunter/forager
Structures for colour - reflectance - blue/green - interference using hollow structures - iridescence
Structure:
Rachis - hollow, central shaft providing backbone
Barbs - extend either side
Barbules + hooks - stiffness + flexibility - fastens feathers together
Down feathers
Smaller than contour
Lack barbules + hooks
Soft + fluffy
Insulation - closest to skin
Semiplume
Intermediate between contour
Help keep form
Help with insulation
FIloplume
Hairlike - few barbs at tip
Covered by other feathers
Pressure + vibration receptors - many have endings
Help contour stay in correct shape + form
Bristle
Stiff - few barbs
Occur round eyes + mouth of some birds
Protective/filters
Funnels for insectivores
Feather function
Crypsis - blending in background - predation - anti predation
Attraction - mates - males usually brighter - stand out - females not bright to protect young
Insulation - primary evolution driving force of feathers - vital for endothermy - denser plumage in winter
Flight
Feather care
Preening - most basic care - bill on feathers- clean - rearrange plumage - apply oils from uropygial gland - water proofing
Allopreening - preening each other - social function
Bathing - water - worse flying - hide after - sunning - spread out in sun - softens waxes so can be removed - anting - lie in ants that produce formic acid and deal with ectoparasites
Moulting - replaced old feathers with new ones - 1+ times a year - lot of energy - not in breeding/migrating seasons - replaced in orderly predictable sequence
Adaptions for flight
feathers - lightweight - strong - streamlined - flexible
Lightening - skeleton - reduced no of bones- hollow - lack marrow - skull lost heavy jaw - beak is toothless - gizzard for grinding
Reproduction - organs enlarge seasonally - oviparous - external fertilisation
Strengthening:
- skeleton - fusion of bones - wish bone - keel extension of breast bone - anchor of flight muscles - deeper keel = more powerful flight
- muscles - pectoralis - up to 35% total weight - supracoracoideus pulls wings up
Brain + sensory organs - main sense is sight - large eyes - large brain for processing visual info
Wings - Elaborate joints - fused hand bones - powerful tendons + compact muscles - airfoil shape
Flight mechanics
Acting forces - weight vs lift - drag vs propulsion
Lift generated by flow of air over wings - speed of air flow relates to pressure
Airfoil shape - air travels further over top - speeds up - decreases pressure - wing sucked upward/ shorter distance underwing- air slower - pressure increases - wing pushed upward
More curved the airfoil - greater the lift
friction drag - air flow over body
Induced drag - consequence of lift - swirling vortices created at wing tips - produces downwash
Thrust created by wing flapping - most from downstroke - simple recovery upstroke
Gliding - weight used to overcome air resistance to forward motion - heavier birds can glide further with same loss of height
Soaring - Maintain of altitude without flapping:
slope soaring - wind deflected upward by side of object
Dynamic soaring - local updrafts where wind meets waves
Thermal soaring - uneven heating of air near ground- convection currents - fly in circles within
Hovering - maintaining stationary positon:
Wind hovering - fly into headwind - use thrust to stay in same position
True hovering - wing airfoil shape in up + down stroke- humming bird
Wing loading
body weight/wing area
low = large wing area for body - more efficient flight
high = small wing area for weight - energetically costly - difficulty taking off
Aspect ratio
Wing area 2/ wing breadth
high = fast - low manoeuvrability
Elliptical wing
Low AR - good manoeuvrability
Woodpeckers - forest raptors
Short rounded - large wing slots
Fast take off - pheasants + grouse
Large amounts of induced drag - slotting helps reduce
High lift wings
Moderate AR
Broad wing
Heavily cambered
Carry heavy load - minimise energy
Terrestrial species - eagles - vultures - storks
