Abstract
Conserving biodiversity in the face of expanding human degradation of ecosystems is facilitated by understanding the natural state of communities prior to the impact of anthropogenic disruptions. Reconstructing communities and ecosystems as they existed in the past requires data from the fossil record on their species composition, richness, and abundance. Fossil data are potentially different from data collected from living communities in their spatial, temporal, and taxonomic scales and these differences must be understood so that accurate comparisons can be made between past and present states of living communities. Fifty-four long-term ecological studies of a wide range of taxon groups (mammals, invertebrates, plants, corals) and habitat types (marine, terrestrial, freshwater) were surveyed from the published ecological literature to determine the range of spatial, temporal and taxonomic scales at which data are commonly collected in ecological research. Long-term ecological studies encompass spatial scales from 50m2 to 100,000km2 and temporal scales from 5 to 100 years. Most studies resolve taxa to the species level and count individuals, although plant and coral studies sometimes quantify species by percent cover. All taxon groups and habitat types were studied across a wide range of spatial and temporal scales. Whether or not data from fossils can be collected and analysed at scales comparable to data from living communities depends on the type of organism, as well as the taphonomic circumstances of preservation, accumulation and deposition. Marine invertebrates can be sampled at comparable spatial and taxonomic scales to living invertebrates, but time averaging degrades the temporal resolution of the fossil deposits. Vertebrate fossils provide data at comparable taxonomic scales with some reduction in spatial and temporal resolution relative to live data. Plant fossils and pollen are capable of being sampled at temporal resolutions comparable to modern ecological studies, but pollen data are prone to spatial averaging and have much poorer taxonomic resolution than censuses of living communities. It is important to be mindful of the limitations that scale mismatches produce in the ability to use fossil data to resolve ecological events and to compare the details of ecological composition and structure between the present and the past.
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References
Addessi L (1994) Human disturbance and long-term changes on a rocky intertidal community. Ecol Appl 4:786–797
Allmon W (2009) Speciation and shifting baselines: Prospects for reciprocal illumination between evolutionary paleobiology and conservation biology. In: Dietl GP, Flessa KW (eds) Conservation paleobiology. The Paleontological Society, Boulder CO 15:245–274
Anderson TW, Levac E, Lewis C (2007) Cooling in the Gulf of St. Lawrence and estuary region at 9.7 to 7.2 (super 14) C ka (11.2-8.0 cal ka); palynological response to the PBO and 8.2 cal ka cold events, Laurentide ice sheet air-mass circulation and enhanced freshwater runoff. Palaeogeogr Palaeoclimatol Palaeoecol 246:75–100
Aronson MFJ, Galatowitsch S (2008) Long-term vegetation development of restored prairie pothole wetlands. Wetlands 28:883–895
Aronson RB, Precht WF (1997) Stasis, biological disturbance, and community structure of a Holocene coral reef. Paleobiology 23:326–346
Aronson RB, Macintyre IG, Precht WF, Murdoch TJT (2002) The expanding scale of species turnover events on coral reefs in Belize. Ecol Monogr 72:233–249
Augustin D, Richard G, Salvat B (1999) Long-term variation in mollusc assemblages on a coral reef, Moorea, French Polynesia. Coral Reefs 18:292–296
Balčiauskas L (2005) Results of the long-term monitoring of small mammal communities in the Ignalina nuclear power plant region (Druksiai LTER site). Acta Zool Litu 15:1392–1657
Bates JD, Miller RF, Svejcar T (2007) Long-term vegetation dynamics in a cut western juniper woodland. West N Am Nat 67:549–561
Behrensmeyer AK, Western D, Boaz DE (1979) New perspectives in vertebrate paleoecology from a recent bone assemblage. Paleobiology 5:12–21
Behrensmeyer AK, Kidwell SM, Gastaldo RA (2000) Taphonomy and paleobiology. Paleobiology 26(suppl):103–147
Bennie J, Hill MO, Baxter R, Huntley B (2006) Influence of slope and aspect on long-term vegetation change in British chalk grasslands. J Ecol 94:355–368
Bennington JB (2003) Transcending patchiness in the comparative analysis of paleocommunities: a test case from the Late Cretaceous of New Jersey. Palaios 18:22–33
Bennington JB, Rutherford SD (1999) Precision and reliability in paleocommunity comparisons based on cluster-confidence intervals: how to get more statistical bang for your sampling buck. Palaios 14:505–515
Bennington JB, DiMichele WA, Badgley C et al (2009) Critical issues of scale in paleoecology. Palaios 24:1–4
Berumen ML, Pratchett MS (2006) Recovery without resilience: persistent disturbance and long-term shifts in the structure of fish and coral communities at Tiahura Reef, Moorea. Coral Reefs 25:647–653
Billet DSM, Bett BJ, Rice AL, Thurston MH, Galéron J, Sibuet M, Wolff GA (2001) Long-term change in the megabenthos of the Porcupine Abyssal Plain (NE Atlantic). Prog Oceanogr 50:325–348
Bragg DC, Shelton MG (2011) Lessons from 72 years of monitoring a once-cut pine-hardwood stand on the Crossett Experimental Forest, Arkansas, USA. For Ecol Manag 261:911–922
Brauer A, Endres C, Guenter C, Litt T, Stebich M, Negendank JW (1999) High resolution sediment and vegetation responses to Younger Dryas climate change in varved lake sediments from Meerfelder Maar, Germany. Quat Sci Rev 18:321–329
Bretsky PW, Bretsky SS (1975) Succession and repetition of Late Ordovician fossil assemblages from the Nicolet River Valley, Quebec. Paleobiolology 1:225–237
Brown ME, Kowalewski M, Neves RJ, Cherry DS, Schreiber ME (2005) Freshwater mussel shells as environmental chronicles: geochemical and taphonomic signatures of mercury-related extirpations in the North Fork Holston River, Virginia. Environ Sci Technol 39:1455–1462
Burnham RJ (2001) Is conservation biology a paleontological pursuit? Palaios 16:423–424
Bush MB (1995) Neotropical plant reproductive strategies and fossil pollen representation. Am Nat 145:594–609
Buzas MA (1968) On the spatial distribution of formaminifera. Contrib Cushman Found Foraminifer Res 19:1–11
Carré MI, Bentaleb I, Fontugne M, Lavallee D (2005) Strong El Nino events during the early Holocene: stable isotope evidence for Peruvian sea shells. Holocene 15:42–47
Chapman RA, Heitzman E, Shelton MG (2006) Long-term changes in forest structure and species composition of an upland oak forest in Arkansas. For Ecol Manag 236:85–92
Chapman CA, Struhsaker TT, Skorupa JP, Snaith TV, Rothman JM (2010) Understanding long-term primate community dynamics: implications of forest change. Ecol Appl 20:179–191
Connell JH, Slatyer RO (1977) Mechanisms of succession in natural communities and their role in community stability and organization. Am Nat 111:1119–1144
Connell JH, Hughes TP, Wallace CC (1997) A 30-year study of coral abundance, recruitment, and disturbance at several scales in space and time. Ecol Monogr 67:461–488
Czerepko J (2008) A long-term study of successional dynamics in the forest wetlands. For Ecol Manag 255:630–642
Danby RK, Koh S, Hik DS, Price LW (2011) Four decades of plant community change in the alpine tundra of southwest Yukon, Canada. Ambio 40:660–671
Daufresne MM, Roger C, Capra H, Lamouroux N (2003) Long term changes within the invertebrate and fish communities of the upper Rhone River: effects of climate factors. Glob Change Biol 10:124–140
Davis MB (2000) Palynology after Y2K – Understanding the source area of pollen in sediments. Annu Rev Earth Planet Sci 28:1–18
Dettman DL, Flessa KW, Roopnarine PD, Schöne BR, Goodwin DH (2004) The use of oxygen isotope variation in shells of estuarine mollusks as a quantitative record of seasonal and annual Colorado River discharge. Geochim Cosmochim Acta 68:1253–1263
Drayton B, Primack RB (1996) Plant species lost in an isolated conservation area in metropolitan Boston from 1894 to 1993. Conserv Biol 10:30–39
Dunbar RB, Cole JE (1993) Coral records of ocean-atmosphere variability. NOAA Clim Glob Change Prog Spec Rep 10:1–38
Edinger EN, Burr GS, Pandolfi JM, Ortiz JC (2007) Age accuracy and resolution of quaternary corals used as proxies for sea level. Earth Planet Sci Lett 253:37–49
Elliott KJ, Vose JM, Swank WT (1999) Long-term patterns in vegetation-site relationships in a southern Appalachian forest. J Torrey Bot Soc 126:320–334
Elmendorf SC, Harrison SP (2011) Is plant community richness regulated over time? Contrasting results from experiments and long-term observations. Ecology 92:602–609
Faith J (2011) Ungulate community richness, grazer extinctions, and human subsistence behavior in Southern Africa’s Cape Floral Region. Palaeogeogr Palaeoclimatol Palaeoecol 306:219–227
Feeley KJ, Davies SJ, Perez R, Hubbell SP, Foster RB (2011) Directional changes in the species composition of a tropical forest. Ecology 92:871–882
Ferguson CA (2008) Nutrient pollution and the molluscan death record: use of mollusc shells to diagnose environmental change. J Coast Res 24:250–259
Ferguson CA, Miller AI (2007) A sea change in Smuggler's Cove? Detection of decadal-scale compositional transitions in the subfossil record. Palaeogeogr Palaeoclimatol Palaeoecol 254:418–429
Feurdean A, Bennike O (2004) Late Quaternary palaeoecological and palaeoclimatological reconstruction in the Gutaiului Mountains, northwest Romania. J Quat Sci 19:809–827
Foote M, Miller AI (2007) Principles of paleontology. WH Freeman, New York
Foster DR, Zebryk TM (1993) Long-term vegetation dynamics and disturbance history of a Tsuga-dominated forest in New England. Ecology 74:928–998
Gaston KJ (2000) Global patterns in biodiversity. Nature 405:220–227
Gehlhausen SM, Schwartz MW, Augsperger CK (2000) Vegetation and microclimatic edge effects in two mixed-mesophytic forest fragments. Plant Ecol 147:21–35
Gilinsky NL, Bennington J (1994) Estimating numbers of whole individuals from collections of body parts; a taphonomic limitation of the paleontological record. Paleobiology 20:245–258
Greenstein BJ, Curran HA, Pandolfi JM (1998) Shifting ecological baselines and the demise of Acropora cervicornis in the western North Atlantic and Caribbean Province: a Pleistocene perspective. Coral Reefs 17:249–261
Hadly EA (1996) Influence of Late Holocene climate on northern rocky mountain mammals. Quat Res 46:298–310
Hadly EA (1999) Fidelity of terrestrial vertebrate fossils to a modern ecosystem. Palaeogeogr Palaeoclimatol Palaeoecol 149:389–409
Hadly EA, Barnosky AD (2009) Vertebrate fossils and the future of conservation biology. In: Dietl GP, Flessa KW (eds) Conservation paleobiology. The Paleontological Society, Boulder CO 15:39–59
Hadly EA, Maurer BA (2001) Spatial and temporal patterns of species diversity in montane mammal communities of western North America. Evol Ecol Res 3:477–486
Hairston NG (1959) Species abundance and community structure. Ecology 40:404–415
Hashimoto TR, Saintilan N, Haberle SG (2006) Mid-Holocene development of mangrove communities featuring Rhizophoraceae and geomorphic change in the Richmond River estuary, New South Wales, Australia. Geogr Res 44:63–76
Ilg C, Dziock F, Foeckler F et al (2008) Long-term reactions of plants and macroinvertebrates to extreme floods in floodplain grasslands. Ecology 89:2392–2398
Jackson JBC (1997) Reefs since Columbus. Coral Reefs 16(suppl):S23–S32
Jackson ST, Gray ST, Shuman B (2009) Paleoecology and resource management in a dynamic landscape: case studies from the Rocky Mountain headwaters. In: Dietl GP, Flessa KW (eds) Conservation paleobiology. The Paleontological Society, Boulder CO 15:62–80
Jones DS, Arthur MA, Allard DJ (1989) Sclerochronological records of temperature and growth from shells of Mercenaria mercenaria from Narragansett Bay, Rhode Island. Mar Biol 102:225–234
Kardol P, Todd DE, Hanson PJ, Mulholland PJ (2010) Initial community composition interacts with climatic variability in affecting long-term forest dynamics. J Veg Sci 21:627–642
Kealhofer LL, Penny DD (1998) A combined pollen and phytolith record for fourteen thousand years of vegetation change in northeastern Thailand. Rev Palaeobot Palynol 103:83–93
Kidwell SM (2002) Time-averaged molluscan death assemblages: palimpsests of richness, snapshots of abundance. Geology 30:803–806
Kidwell SM (2007) Distance between living and death assemblages as evidence for anthropogenic ecological change. Proc Natl Acad Sci USA 104:17701–17706
Kidwell SM (2008) Ecological fidelity of open marine molluscan death assemblages: effects of post-mortem transportation, shelf health, and taphonomic inertia. Lethaia 41:199–217
Kidwell SM (2009) Evaluating human modification of shallow marine ecosystems: mismatch in composition of molluscan living and time-averaged death assemblages. In: Dietl GP, Flessa KW (eds) Conservation paleobiology. The Paleontological Society, Boulder CO 15:113–139
Kidwell SM, Bosence DWJ (1991) Taphonomy and time-averaging of marine shelly faunas. In: Allison PA, Briggs DEG (eds) Taphonomy, releasing data locked in the fossil record. Plenum, New York
Kito N, Ohkuro Y (2011) Vegetation response to climatic oscillations during the last glacial-interglacial transition in northern Japan. Quat Int 254:118–128
Klinger R (2006) The interaction of disturbances and small mammal community dynamics in a lowland forest in Belize. J Anim Ecol 75:1227–1238
Kowalewski M (2009) The youngest fossil record and conservation biology: Holocene shells as eco-environmental recorders. In: Dietl GP, Flessa, KW (eds) Conservation paleobiology. The Paleontological Society, Boulder CO 15:1–24
Kowalewski M, Avila Serrano GE, Flessa KW, Goodfriend GA (2000) Dead delta’s former productivity: two trillion shells at the mouth of the Colorado River. Geology 28:1059–1062
Laub RS (2003) The Pleistocene fauna of the Hiscock site. Bull Buffalo Soc Nat Sci 37:69–82
Laurance WF, Laurance SG, Hilbert DW (2008) Long-term dynamics of a fragmented rainforest mammal assemblage. Conserv Biol 22:1154–1164
Lawrence JE, Lunde KB, Mazor RD, Beche LA, McElravy EP, Resh VH (2010) Long-term macroinvertebrate responses to climate change: implications for biological assessment in Mediterranean-climate streams. J North Am Benthol Soc 29:1424–1440
Le Fur S, Fara E, Vignaud P (2011) Effect of simulated faunal impoverishment and mixture on the ecological structure of modern mammal faunas: implications for the reconstruction of Mio-Pliocene African palaeoenvironments. Palaeogeogr Palaeoclimatol Palaeoecol 305:295–309
Lwanga JS, Butynski TM, Struhsaker TT (2000) Tree population dynamics in Kibale National Park, Uganda 1975–1998. Afr J Ecol 38:238–247
Lyons-Weiler JF (1992) Palynological evidence for regional, synchronous, Holocene climate changes in Amazonia and their influence on evolution in the tropics. Dissertation, The Ohio State University
Magurran AE, Baillie SR, Buckland ST et al (2010) Long-term datasets in biodiversity research and monitoring: assessing change in ecological communities through time. Trends Ecol Evol 25:574–582
Markich SJ, Jeffree RA, Burke PT (2002) Freshwater bivalve shells as archival indicators of metal pollution from a copper-uranium mine in tropical northern Australia. Environ Sci Technol 36:821–832
Martin TE (2007) Climate correlates of 20 years of trophic changes in a high-elevation riparian system. Ecology 88:367–380
Martin CW, Bailey AS (1999) Twenty years of change in a northern hardwood forest. For Ecol Manag 123:253–260
McAuliffe JR, Van Devender TR (1998) A 22,000-year record of vegetation change in the north-central Sonoran desert. Palaeogeogr Palaeoclimatol Palaeoecol 141:253–275
McClanahan TR, Ateweberhan M, Omukoto J (2008) Long-term changes in coral colony size distributions on Kenyan reefs under different management regimes and across the 1998 bleaching event. Mar Biol 153:755–768
McEwan RW, Muller RN (2006) Spatial and temporal dynamics in canopy dominance of an old-growth central Appalachian forest. Can J For Res 36:1536–1550
Meiners SJ (2007) Native and exotic plant species exhibit similar population dynamics during succession. Ecology 88:1098–1104
Meldahl KH, Flessa KW, Cutler AH (1997) Time-averaging and postmortem skeletal survival in benthic fossil assemblages; quantitative comparisons among Holocene environments. Paleobiology 23:209–222
Miller W III (1986) Paleoecology of benthic community replacement. Lethaia 19:225–231
Miller AI (1988) Spatial resolution in subfossil molluscan remains: implications for paleobiological analyses. Paleobiology 14:91–103
Moritz C, Patton JL, Conroy CJ, Parra JL, White GC, Beissinger SR (2008) Impact of a century of climate change on small-mammal communities in Yosemite National Park, USA. Science 322:261–264
Munson SM, Webb RH, Hubbard JA (2011) A comparison of methods to assess long-term changes in Sonoran desert vegetation. J Arid Environ 75:1228–1231
Østbye E, Hogstad O, Østbye K, Lien L, Framstad E, Breiehagen T (2007) Structure and dynamics of a high mountain wetland bird community in southern Norway: an 18-year study of waders and gulls. Ornis Nor 30:4–20
Pandolfi JM (1992) A palaeobiological examination of the geological evidence for recurring outbreaks of the crown-of-thorns starfish, Acanthaster planci (L.). Coral Reefs 11:87–93
Pazonyi P (2004) Mammalian ecosystem dynamics in the Carpathian Basin during the last 27,000 years. Palaeogeogr Palaeoclimatol Palaeoecol 212:295–314
Pellerin S, Mercure M, Desaulniers AS, Lavoie C (2008) Changes in plant communities over three decades on two disturbed bogs in southeastern Québec. Appl Veg Sci 12:107–118
Perry CT, Smithers SG, Palmer SE, Larcombe PP, Johnson KG (2008) 1200 year paleoecological record of coral community development from the terrigenous inner shelf of the Great Barrier Reef. Geology 36:691–694
Prach K, Walker LR (2011) Four opportunities for studies of ecological succession. Trends Ecol Evol 26:119–123
Rahlao SJ, Hoffman MT, Todd SW, McGrath K (2008) Long-term vegetation change in the Succulent Karoo, South Africa following 67 years of rest from grazing. J Arid Environ 72:808–819
Roche RC, Perry CT, Johnson KG, Sultana K, Smithers SG, Thompson AA (2011) Mid-Holocene coral community data as baselines for understanding contemporary reef ecological states. Palaeogeogr Palaeoclimatol Palaeoecol 299:159–167
Rogers DA, Rooney TP, Olson D, Waller DM (2008) Shifts in southern Wisconsin forest canopy and understory richness, composition, and heterogeneity. Ecology 89:2482–2492
Rooney TP, Wiegmann SM, Rogers DA, Waller DM (2004) Biotic impoverishment and homogenization in unfragmented forest understory communities. Conserv Biol 18:787–798
Rosenzweig ML (1998) Preston’s ergodic conjecture: the accumulation of species in space and time. In: McKinney ML, Drake JA (eds) Biodiversity dynamics. Columbia University Press, New York
Sagarin RD, Barry JP, Gilman SE, Baxter CH (1999) Climate-related change in an intertidal community over short and long time scales. Ecol Monogr 69:465–490
Samonil P, Vrska T (2008) Long-term vegetation dynamics in the Sumava Mts. Natural spruce-fir-beech forests. Plant Ecol 196:197–214
Schiel DR, Steinbeck JR, Foster MS (2004) Ten years of induced ocean warming causes comprehensive changes in marine benthic communities. Ecology 85:1833–1839
Schleyer MH, Kruger A, Celliers L (2008) Long-term community changes on a high-latitude coral reef in the Greater St Lucia Wetland Park, South Africa. Mar Pollut Bull 56:493–502
Schmitt DN, Madsen DB, Lupo KD (2002) Small-mammal data on early and middle Holocene climates and biotic communities in the Bonneville Basin, USA. Quat Res 58:255–260
Schreiber J, Brauns M (2010) How much is enough? Adequate sample size for littoral macroinvertebrates in lowland lakes. Hydrobiologia 649:365–373
Shenbrot G, Krasnov B, Burdelov S (2010) Long-term study of population dynamics and habitat selection of rodents in the Negev desert. J Mamm 91:776–786
Small CJ, McCarthy BC (2002) Spatial and temporal variability of herbaceous vegetation in an eastern deciduous forest. Plant Ecol 164:37–48
Soloman CT, Olden JD, Johnson PTJ, Dillon RT Jr, Vander Zanden MJ (2010) Distribution and community-level effects of the Chinese mystery snail (Bellamya chinensis) in northern Wisconsin lakes. Biol Invasions 12:1591–1605
Soulé ME (1985) What is conservation biology? BioSci 35:727–734
Steadman DW (2003) Long-term change and continuity in the Holocene bird community of western New York State. Bull Buffalo Soc Nat Sci 37:121–132
Stearns F, Likens GE (2002) One hundred years of recovery of a pine forest in northern Wisconsin. Am Midl Nat 148:2–19
Stouffer PC, Bierregaard RO Jr, Strong C, Lovejoy TE (2006) Long-term landscape change and bird abundance in Amazonian rain forest fragments. Conserv Biol 20:1212–1223
Stroh CL, De Steven D, Guntenspergen GR (2008) Effect of climate fluctuations on long-term vegetation dynamics in Carolina bay wetlands. Wetlands 28:17–27
Surge DM, Lohmann KC, Goodfriend GA (2003) Reconstructing estuarine conditions: oyster shells as recorders of environmental change, southwest Florida. Estuar Coast Shelf Sci 57(5–6):737–756
Terry RC (2007) Holocene small mammals of the Great Basin: tracking recent richness declines through live/dead analysis of raptor-generated faunal remains. Geol Soc Am Abstr Prog 39:168
Thibault KM, Ernest SKM, White EP, Brown JH, Goheen JR (2010) Long-term insights into the influence of precipitation on community dynamics in desert rodents. J Mamm 91:787–797
Thomas II, Enright NJ, Kenyon CE (2001) The Holocene history of Mediterranean-type plant communities, Little Desert National Park, Victoria, Australia. Holocene 11:691–697
Tomasovych A, Kidwell SM (2009) Preservation of spatial and environmental gradients by death assemblages. Paleobiolology 35:119–145
Van der Meij SET, Moolenbeek RG, Hoeksema BW (2009) Decline of Jakarta Bay molluscan fauna linked to human impact. Mar Pollut Bull 59:101–107
Vincke C, Diédhiou I, Grouzis M (2010) Long term dynamics and structure of woody vegetation in the Ferlo (Senegal). J Arid Environ 74:268–276
Visser JM, Sasser CE (1995) Changes in tree species composition, structure and growth in a bald cypress-water tupelo swamp forest, 1980–1990. For Ecol Manag 72:119–129
Vitousek PM, Mooney HA, Lubchenco J, Melillo JM (1997) Human domination of the earth’s ecosystems. Science 277:494–499
Von Oheimb G, Brunet J (2007) Dalby Söderskog revisited: long-term vegetation changes in a south Swedish deciduous forest. Acta Oecol 31:229–242
Walbran PD, Henderson RA, Faithful JW, Polach HA, Sparks RJ, Wallace GG, Lowe DC (1989) Crown-of-thorns starfish outbreaks on the Great Barrier Reef; a geological perspective based upon the sediment record. Coral Reefs 8:67–78
Walker KR, Alberstadt LP (1975) Ecological succession as an aspect of structure in fossil communities. Paleobiolology 1:238–257
Walker KR, Diehl WW (1986) The effect of synsedimentary substrate modification on the composition of paleocommunities: paleoecologic succession revisited. Palaios 1:65–74
Walker KR, Parker WC (1976) Population structure of a pioneer and a later stage species in an Ordovician ecological succession. Paleobiology 2:191–201
Warme JE (1971) Paleoecological aspects of a modern coastal lagoon. Univ Calif Publ Geol Sci 87:1–110
Western D (1980) Linking the ecology of past and present mammal communities. In: Behrensmeyer AK, Hill AP (eds) Vertebrate taphonomy and paleobiology. University of Chicago Press, Chicago
Woods KD (2000) Dynamics in late-successional hemlock-hardwood forests over three decades. Ecology 81:110–126
Worthy TH (1997) Quaternary fossil fauna of South Canterbury, South Island, New Zealand. J R Soc N Z 27:67–162
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Bret Bennington, J., Aronson, M.F.J. (2012). Reconciling Scale in Paleontological and Neontological Data: Dimensions of Time, Space, and Taxonomy. In: Louys, J. (eds) Paleontology in Ecology and Conservation. Springer Earth System Sciences. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-25038-5_4
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