Lecture i & ii: Evidence Of Climate Change & Natural Causes of CC Flashcards
Define climate
Mean atmospheric condit n of an area measured over substantial period time
Define climate variability
Variat n/ change in mean state & other statistical property of atmosphere (precipitat n, insolat n, humidity, etc) eg standard deviat n & occurence of extremes of climate on all spatial & temporal scales beyond that of indiv weather events
Describe Quaternary period
- most recent geological period in earth’s history
- started w Pleistocene Epoch abt 2.5 million years AGO
- Holocene Epoch (which we currently live in) followed abt 11 700 yrs AGO
- Pleistocene —> rapid growth & retreat of ice sheet (unstable). End of last glacial maximum marked start of Holocene
- Holocene —> period of relative warming (interglacial). Oni some events of cooling, drought but otherwise quite stable
- prior to year 1900, most climate changes r considered natural (not caused by anthropogenic factors)
Name sources of evidence of climate change since the last ice age
Main
- Ice cores
- Ocean/Marine Sediment cores
Extra
- Paleolakes & River Terraces
- Sea-lvl change (fr coastlines & seas)
- Biological (Tree ring dating)
- Contemporary Recorded evidences
Explain evidence from ice cores
- scientists drilled, extracted ice cores fr Greenland & Antartic ice sheets
- used isotope ratios determine climatic changes since last Ice Age (>10 000 yr ago)
eg data show CO2 conc vv low during glacials (~180ppm) & higher during warmer interglacials (~280ppm) - isotope ratio change w climatic variat n
- light 16O water molecules evaporate more readily but condense less readily vs 18O water molecules
=> lesser 16O in ice core mean higher rate evaporat n, indicate higher temp - high temp, more 18O water molecules (high isotope ratio 18O to 16O)
- in cold climate, more 16O vs heavy 18O water molecules (low isotope ratio 18O to 16O)
Explain evidence from ocean/maritime sediment cores
- radiometric dating of foraminifera skeletons
- nature of O isotope -> give us idea on temp, salinity, nutrient content in ocean
- results partly match pattern provided in Milankovitch cycles
- cores reflect there were 8 glacial built up on abt 100 000 year cycle -> similar to Milankovitch’s eccentricity theory (cool phase)
- decrease in ice vol occur at 23000 and 41000 year intervals (same as precession & tilt frequencies (warm) )
Explain biological evidence
- diff width of tree ring contain annual record of climate condit n of past, as tree growth greatly influenced by climatic condit n eg temp, precipita n
eg warm, wet in tropical region favour growth -> larger tree ring
BUT
drought year -> narrow tree-ring
Explain evidence from current day coastlines and sea levels
- sea lvl began rise ~19 000 year ago, reached present lvl abt 7000 year ago
Two processes account for global rise of sea lvl:
1. thermal expans n ocean
2. Melting land based ice sheets
- global sea lvl hv rise btw 10-20cm over past century, continue at accelerated rate in coming years
- rising sea lvl is real, current danger for 2 major types of area:
world mega deltas & low lying countries
eg Maldives in Indian Ocean, Kiribati in Central Pacific Ocean
Define climate change
signi rise in global temperatures, particularly contemporary CC due to enhanced gh effect, causing damage in econ, social, environ, political components
OR
any significant change in statistical property of atmostphere eg temp, precipitat n, humidity, etc, lasting for extended period of time
Name natural causes of climate change
- Milankovitch cycles (orbital forcing theory)
- Sunspot activity
- Internal Feedback Mechanism
Describe Milankovitch cycle
- affect amt solar radiat n & where it reach earth
=> determined by 3 parameters: - orbit eccentricity
- obliquity
- precess n of equinoxes
Explain orbit eccentricity (Milankovitch cycles)
- ~100 000yr cycle
- As eccentricity increase (more elliptical), diff in Earth’s dist fr Sun at orbit’s closest & furthest points oso increase, affecting solar rad n hit earth, & thus severity of seasons
Eg. if winter in N. Hemis occur when the dist btw Earth & Sun is at max, winter will b more severe (the greater the eccentricity, the stronger the effects on seasons)
Explain obliquity (tilt of the Earth, Milankovitch Cycle)
- now tilted 23.5 deg, varies fr approx 21.1 to 24.5 deg in 41 000yr cycle; affect seasons
- greater tilt angle, greater contrast btw summer & winter temp
- bcos greater tilt, more extreme season as each hemis receive more solar rad n during summer & less during winter
=> favour melt retreat ice sheets - places at higher latitudes receive larger insolat n than areas close to equator
- as obliquity decrease, milder the seasons
- warmer winters and cooler summers
- over time, ice sheet build up (reflect more solar rad n)
- promote more cooling
Explain precession of equinoxes (axial wobble, Milankovitch cycle)
- is change in orientat n of earth’s rotational axis
- due to grav force of sun, moon causing earth to bulge at equator, earth wobble like spin top, affecting its rotat n
- makes seasonal contrasts more extreme in one hemis, less in the other
- Vega/15014 (13 000yr ago) Earth reach furthest pt fr sun during S hemis winter, so slightly colder than N. hemis
- Polaris/2014 (present)
- Now (2020), perihelion (nearest to sun) occur at Winter Solstice (winter in N hemis)
- axial precess n make S hemis summer hotter, moderate N hemis winter
- BUT, in 13 000 yr, axial precess n cause reversal of these condit n (more extreme solar rad in N. Hemis, moderate S. hemis seasons)
vs
aphelion (furthest fr sun) -> opp effects
Explain limitation of orbital forcing theory (Milankovitch cycle)
- other factors can oso influence CC
- predict n of CC based on orbital change oni no correspond to CC based on other expl n or evidence
Eg
1. Temp change needed for massive glacial expan n & retreat greater than changes caused by orbital forcing alone
2. Orbital changes shd create smooth changes, but many short-term changes which r abrupt, show “saw-tooth” patterns
