. ‘. Atmospheric and Environmental Effects of the 1783-‐1784 Laki Eruption: A Review and Reassessment’. Web. <http://seismo.berkeley.edu/~manga/LIPS/thordarson03.pdf>.
A. Guevara-Murua. ‘Observations of a Stratospheric Aerosol Veil from a Tropical Volcanic Eruption in December 1808: Is This the Unknown ∼1809 Eruption?’ Climate of the Past 10.5 1707–1707. Web. <https://go.gale.com/ps/i.do?&id=GALE|A481428553&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
‘A New Approach to Assess Long-‐term Lava Flow Hazard and Risk Using GIS and Low-‐cost Remote Sensing: The Case of Mount Cameroon, West Africa’. N.p., n.d. Web. <http://www.tandfonline.com/doi/pdf/10.1080/01431160802167873>.
Abbott, David A., Payson D. Sheets, and Jago Cooper. Surviving Sudden Environmental Change: Answers from Archaeology. 1st ed. Boulder, Colo: University Press of Colorado, 2012. Web. <https://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=5195538870002418&institutionId=2418&customerId=2415>.
Abdullah, Mikrajuddin. ‘Interpretation of Past Kingdoms Poems to Reconstruct the Physical Phenomena in the Past: Case of Great Tambora Eruption 1815’. (2012): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_arxiv1609.09225&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,tambora&offset=0>.
‘After Tambora’. The Economist (20150411): n. pag. Web. <https://www.economist.com/news/briefing/21647958-two-hundred-years-ago-most-powerful-eruption-modern-history-made-itself-felt-around>.
‘Age of the Emeishan Flood Magmatism and Relations to Permian–Triassic Boundary Events’. N.p., n.d. Web. <http://libra.msra.cn/Publication/5357742/age-of-the-emeishan-flood-magmatism-and-relations-to-permian-triassic-boundary-events>.
Alan Robock. ‘The Climatic Aftermath’. Science 295.5558 (2002): n. pag. Web. <https://www.jstor.org/stable/3075904?seq=1#metadata_info_tab_contents>.
Albore Livadie, Claude et al. ‘The Effects of the Avellino Pumice Eruption on the Population of the Early Bronze Age Campanian Plain (Southern Italy)’. Quaternary International 499 (2019): 205–220. Web.
---. ‘The Effects of the Avellino Pumice Eruption on the Population of the Early Bronze Age Campanian Plain (Southern Italy)’. Quaternary International 499 (2019): 205–220. Web.
Alexander, Karen E. et al. ‘Tambora and the Mackerel Year: Phenology and Fisheries during an Extreme Climate Event’. Science Advances 3.1 (2017): n. pag. Web.
Allen, Judy R.M, William A Watts, and Brian Huntley. ‘Weichselian Palynostratigraphy, Palaeovegetation and Palaeoenvironment; the Record from Lago Grande Di Monticchio, Southern Italy’. Quaternary International 73–74 (2000): 91–110. Web.
Allibone, Rachel et al. ‘Dental Fluorosis Linked to Degassing of Ambrym Volcano, Vanuatu: A Novel Exposure Pathway’. Environmental Geochemistry and Health 34.2 (2012): 155–170. Web.
Alloway, Brent V. et al. ‘Archaeological Implications of a Widespread 13th Century Tephra Marker across the Central Indonesian Archipelago’. Quaternary Science Reviews 155 (2017): 86–99. Web.
Alwyn Scarth. ‘La Catastrophe: Mount Pelée and the Destruction of Saint-Pierre, Martinique - Alwyn Scarth - Google Books’. Terra, 2002, n.d. Web. <http://books.google.co.uk/books/about/La_catastrophe.html?id=SxROAQAAIAAJ&redir_esc=y>.
Andreastuti, Supriyati et al. ‘Character of Community Response to Volcanic Crises at Sinabung and Kelud Volcanoes’. Journal of Volcanology and Geothermal Research 382 (2019): 298–310. Web.
Andrei A. Sinitsyn. ‘A Palaeolithic `Pompeii’ at Kostenki, Russia. (Research)’. Antiquity 77.295 9–15. Web. <https://go.gale.com/ps/retrieve.do?tabID=T002&resultListType=RESULT_LIST&searchResultsType=SingleTab&searchType=AdvancedSearchForm&currentPosition=1&docId=GALE%7CA100484921&docType=Article&sort=RELEVANCE&contentSegment=ZONE-MOD1&prodId=AONE&contentSet=GALE%7CA100484921&searchId=R1&userGroupName=uniaber&inPS=true>.
Angela K Diefenbach. ‘Variations in Community Exposure to Lahar Hazards from Multiple Volcanoes in Washington State (USA)’. Journal of Applied Volcanology 4.1 (2015): n. pag. Web. <https://appliedvolc.biomedcentral.com/articles/10.1186/s13617-015-0024-z>.
‘Anja Schmidt’. N.p., n.d. Web. <https://www.researchgate.net/profile/Anja_Schmidt>.
Anja Schmidt, Bart Ostro, Kenneth S. Carslaw, Marjorie Wilson, Thorvaldur Thordarson, Graham W. Mann and Adrian J. Simmons. ‘Excess Mortality in Europe Following a Future Laki-Style Icelandic Eruption’. Proceedings of the National Academy of Sciences of the United States of America 108.38 (2011): 15710–15715. Web. <http://www.jstor.org/stable/41352334?seq=1#page_scan_tab_contents>.
---. ‘Excess Mortality in Europe Following a Future Laki-Style Icelandic Eruption’. Proceedings of the National Academy of Sciences of the United States of America 108.38 (2011): 15710–15715. Web. <http://www.jstor.org/stable/41352334?seq=1#page_scan_tab_contents>.
Anja Schmidt, Claire S. Witham, Nicolas Theys, Nigel A. D. Richards, Thorvaldur Thordarson, Kate Szpek, Wuhu Feng, Matthew C. Hort, Alan M. Woolley, Andrew R. Jones, Alison L. Redington, Ben T. Johnson, Chris L. Hayward, Kenneth S. Carslaw. ‘Assessing Hazards to Aviation from Sulfur Dioxide Emitted by Explosive Icelandic Eruptions’. Journal of Geophysical Research: Atmospheres 119.24 (2014): 14,180-14,196. Web. <https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1002/2014JD022070>.
Anja Schmidt, Susan Leadbetter, Nicolas Theys, Elisa Carboni, Claire S. Witham, John A. Stevenson, Cathryn E. Birch, Thorvaldur Thordarson, Steven Turnock, Sara Barsotti, Lin Delaney, Wuhu Feng, Roy G. Grainger, Matthew C. Hort, Ármann Höskuldsson, Iolanda Ialongo, Evgenia Ilyinskaya, Thorsteinn Jóhannsson, Patrick Kenny, Tamsin A. Mather, Nigel A. D. Richards, Janet Shepherd. ‘Satellite Detection, Long‐range Transport, and Air Quality Impacts of Volcanic Sulfur Dioxide from the 2014–2015 Flood Lava Eruption at Bárðarbunga (Iceland)’. Journal of Geophysical Research: Atmospheres 120.18 (2015): 9739–9757. Web. <https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2015JD023638>.
---. ‘Satellite Detection, Long‐range Transport, and Air Quality Impacts of Volcanic Sulfur Dioxide from the 2014–2015 Flood Lava Eruption at Bárðarbunga (Iceland)’. Journal of Geophysical Research: Atmospheres 120.18 (2015): 9739–9757. Web. <https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2015JD023638>.
Aquila, Valentina et al. ‘Dispersion of the Volcanic Sulfate Cloud from a Mount Pinatubo-like Eruption’. Journal of Geophysical Research: Atmospheres 117.D6 (2012): n/a-n/a. Web.
Arfeuille, F. et al. ‘Volcanic Forcing for Climate Modeling: A New Microphysics-Based Data Set Covering Years 1600–Present’. Climate of the Past 10.1 (2014): 359–375. Web.
Armijos, Maria Teresa et al. ‘Adapting to Changes in Volcanic Behaviour: Formal and Informal Interactions for Enhanced Risk Management at Tungurahua Volcano, Ecuador’. Global Environmental Change 45 (2017): 217–226. Web.
‘Assessing Hazards to Aviation from Sulfur Dioxide Emitted by Explosive Icelandic Eruptions - Schmidt et al, 2014, JGR, Assessing_SO2_aviation_hazards.Pdf’. Web. <http://eprints.whiterose.ac.uk/82709/1/Schmidt%20et%20al%2C%202014%2C%20JGR%2C%20Assessing_SO2_aviation_hazards.pdf>.
Athanassas, C. D. et al. ‘Contouring the Cataclysm: A Geographical Analysis of the Effects of the Minoan Eruption of the Santorini Volcano’. Environmental Archaeology 23.2 (2018): 160–176. Web.
---. ‘Contouring the Cataclysm: A Geographical Analysis of the Effects of the Minoan Eruption of the Santorini Volcano’. Environmental Archaeology 23.2 (2018): 160–176. Web.
Bakkour, Darine et al. ‘The Adaptive Governance of Natural Disaster Systems: Insights from the 2010 Mount Merapi Eruption in Indonesia’. International Journal of Disaster Risk Reduction 13 (2015): 167–188. Web.
Baldini, James U.L., Richard J. Brown, and Jim N. McElwaine. ‘Was Millennial Scale Climate Change during the Last Glacial Triggered by Explosive Volcanism?’ Scientific Reports 5.1 (2015): n. pag. Web.
Balkanski, Y. et al. ‘Mortality Induced by PM2.5 Exposure Following the 1783 Laki Eruption Using Reconstructed Meteorological Fields’. Scientific Reports 8.1 (2018): n. pag. Web.
Barberi, F. et al. ‘The Control of Lava Flow during the 1991–1992 Eruption of Mt. Etna’. Journal of Volcanology and Geothermal Research 56.1–2 (1993): 1–34. Web.
Barberi, F., M. Martini, and M. Rosi. ‘Nevado Del Ruiz Volcano (Colombia): Pre-Eruption Observations and the November 13, 1985 Catastrophic Event’. Journal of Volcanology and Geothermal Research 42.1–2 (1990): 1–12. Web.
Barclay, J. et al. ‘Framing Volcanic Risk Communication within Disaster Risk Reduction: Finding Ways for the Social and Physical Sciences to Work Together’. Geological Society, London, Special Publications 305.1 (2008): 163–177. Web.
Barclay, Jenni et al. ‘Livelihoods, Wellbeing and the Risk to Life During Volcanic Eruptions’. Frontiers in Earth Science 7 (2019): n. pag. Web.
Behringer, Wolfgang, and Pamela E. Selwyn. Tambora and the Year without a Summer: How a Volcano Plunged the World into Crisis. Medford, MA: Polity, 2019. Print.
Bercovici, Antoine et al. ‘Terrestrial Paleoenvironment Characterization across the Permian–Triassic Boundary in South China’. Journal of Asian Earth Sciences 98 (2015): 225–246. Web.
Bethke, Ingo et al. ‘Potential Volcanic Impacts on Future Climate Variability’. Nature Climate Change 7.11 (2017): 799–805. Web.
Biass, Sebastien, and Costanza Bonadonna. ‘A Fast GIS-Based Risk Assessment for Tephra Fallout: The Example of Cotopaxi Volcano, Ecuador’. Natural Hazards 65.1 (2013): 477–495. Web.
---. ‘A Fast GIS-Based Risk Assessment for Tephra Fallout: The Example of Cotopaxi Volcano, Ecuador’. Natural Hazards 65.1 (2013): 477–495. Web.
Black, Benjamin A., Jean-François Lamarque, et al. ‘Acid Rain and Ozone Depletion from Pulsed Siberian Traps Magmatism’. Geology 42.1 (2014): 67–70. Web.
Black, Benjamin A., Erik H. Hauri, et al. ‘Sulfur Isotopic Evidence for Sources of Volatiles in Siberian Traps Magmas’. Earth and Planetary Science Letters 394 (2014): 58–69. Web.
Black, Benjamin A., Ryan R. Neely, and Michael Manga. ‘Campanian Ignimbrite Volcanism, Climate, and the Final Decline of the Neanderthals’. Geology 43.5 (2015): 411–414. Web.
Bond, David P.G., and Stephen E. Grasby. ‘On the Causes of Mass Extinctions’. Palaeogeography, Palaeoclimatology, Palaeoecology 478 (2017): 3–29. Web.
Bottema, Sytze, and Anaya Sarpaki. ‘Environmental Change in Crete: A 9000-Year Record of Holocene Vegetation History and the Effect of the Santorini Eruption’. The Holocene 13.5 (2003): 733–749. Web.
Brá. ‘Climatic Effects and Impacts of the 1815 Eruption of Mount Tambora in the Czech Lands’. Climate of the Past 12.6 (2012): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofa503206931&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,tambora&offset=0>.
Brázdil, Rudolf et al. ‘European Floods during the Winter 1783/1784: Scenarios of an Extreme Event during the “Little Ice Age”’. Theoretical and Applied Climatology 100.1–2 (2010): 163–189. Web.
Brian J. Soden. ‘Global Cooling after the Eruption of Mount Pinatubo: A Test of Climate Feedback by Water Vapor. (Reports)’. Science 296.5568 727–731. Web. <https://go.gale.com/ps/i.do?p=AONE&u=uniaber&id=GALE|A86062245&v=2.1&it=r>.
Brian Zambri, Allegra N. LeGrande, Alan Robock, Joanna Slawinska. ‘Northern Hemisphere Winter Warming and Summer Monsoon Reduction after Volcanic Eruptions over the Last Millennium’. Journal of Geophysical Research: Atmospheres 122.15 (2017): 7971–7989. Web. <https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2017JD026728>.
Buizert, Christo et al. ‘Abrupt Ice-Age Shifts in Southern Westerly Winds and Antarctic Climate Forced from the North’. Nature 563.7733 (2018): 681–685. Web.
Campbell, Bruce M. S. ‘GLOBAL CLIMATES, THE 1257 MEGA-ERUPTION OF SAMALAS VOLCANO, INDONESIA, AND THE ENGLISH FOOD CRISIS OF 1258’. Transactions of the Royal Historical Society 27 (2017): 87–121. Web.
Cao, Shuji. ‘Mt. Tambora, Climatic Changes, and China’s Decline in the Nineteenth Century’. Journal of World History 23.3 (2012): 587–607. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_museS1527805012300043&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,tambora&offset=0>.
Cashman, K.V., and G. Giordano. ‘Volcanoes and Human History’. Journal of Volcanology and Geothermal Research 176.3 (2008): 325–329. Web.
‘Central Mediterranean Explosive Volcanism and Tephrochronology during the Last 630 Ka Based on the Sediment Record from Lake Ohrid | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0277379119305712?token=963CD51172E1708D01C09E5C4667F89C6CE9FD3F957B0177EC133AC6F6B960CF331F3C2E140EE61CE2D2AC8BB5E2FB1F>.
‘Changes in Mid- and Far-Field Human Landscape Use Following the Laacher See Eruption (c. 13,000 BP) | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618214004625?token=929B4CAB03EC49E56F14B90156292EAAF6E8D54F7094F7B6CF5AE121276CECE216DD6C7A1DA67398981B648F9A2252DA>.
Chester, David K. Volcanoes and Society. London: E. Arnold, 1994. Print.
Chester, David K, Christopher J.L Dibben, and Angus M Duncan. ‘Volcanic Hazard Assessment in Western Europe’. Journal of Volcanology and Geothermal Research 115.3–4 (2002): 411–435. Web.
Chester, David K., Angus M. Duncan, and Christopher J.L. Dibben. ‘The Importance of Religion in Shaping Volcanic Risk Perception in Italy, with Special Reference to Vesuvius and Etna’. Journal of Volcanology and Geothermal Research 172.3–4 (2008): 216–228. Web.
Chester, David K., Angus M. Duncan, and Heather Sangster. ‘Human Responses to Eruptions of Etna (Sicily) during the Late-Pre-Industrial Era and Their Implications for Present-Day Disaster Planning’. Journal of Volcanology and Geothermal Research 225–226 (2012): 65–80. Web.
Clarkson, Chris. ‘Continuity and Change in the Lithic Industries of the Jurreru Valley, India, before and after the Toba Eruption.(Report)’. Quaternary International 258 (2014): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofa285620226&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22toba%20eruption%22&offset=0>.
Cole-Dai, Jihong et al. ‘Cold Decade (AD 1810–1819) Caused by Tambora (1815) and Another (1809) Stratospheric Volcanic Eruption’. Geophysical Research Letters 36.22 (2009): n. pag. Web.
‘Combining Historical and 14C Data to Assess Pyroclastic Density Current Hazards in BaNos City near Tungurahua Volcano (Ecuador) | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618215006527?token=4101E87BDEF7DB65923F9AA1B5FC04E275004933C8457E4B5DFF9A5C5FF6FA744CA133B014E81D6C792BA3B7CC418437>.
‘Communicating Eruption and Hazard Forecasts on Vesuvius, Southern Italy’. Web. <http://www.ucl.ac.uk/volcanoscope/files/pdf%20files/Solana%20et%20al_Hazard%20Perception_Vesuvius_JVGR_2008.pdf>.
Connor, C. B. ‘Exploring Links between Physical and Probabilistic Models of Volcanic Eruptions: The Soufrière Hills Volcano, Montserrat’. Geophysical Research Letters 30.13 (2003): n. pag. Web.
‘Constraints on the Volume and Rate of Deccan Traps Flood Basalt Eruptions Using a Combination of High-Resolution Terrestrial Mercury Records and Geochemical Box Models | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0012821X19304133?token=9B50E6970E7293FB00EDE636D74F62EB0BA45C33FA245DAD1476902AD1287E896D7A6219235DCC54A359E42D94D895D0>.
Convertito, Vincenzo, and Aldo Zollo. ‘Assessment of Pre-Crisis and Syn-Crisis Seismic Hazard at Campi Flegrei and Mt. Vesuvius Volcanoes, Campania, Southern Italy’. Bulletin of Volcanology 73.6 (2011): 767–783. Web.
Cooper, Claire L. et al. ‘Evaluating the Relationship between Climate Change and Volcanism’. Earth-Science Reviews 177 (2018): 238–247. Web.
Costa, A. et al. ‘Quantifying Volcanic Ash Dispersal and Impact of the Campanian Ignimbrite Super-Eruption’. Geophysical Research Letters 39.10 (2012): n/a-n/a. Web.
‘Countries | UNITAR’. N.p., n.d. Web. <https://unitar.org/maps/countries>.
Courtillot, V et al. ‘On Causal Links between Flood Basalts and Continental Breakup’. Earth and Planetary Science Letters 166.3–4 (1999): 177–195. Web.
Cousins, Claire R., and Ian A. Crawford. ‘Volcano-Ice Interaction as a Microbial Habitat on Earth and Mars’. Astrobiology 11.7 (2011): 695–710. Web.
‘Cp-2017-147.Pdf’. Web. <https://www.clim-past-discuss.net/cp-2017-147/cp-2017-147.pdf>.
Cui, Ying, and Lee R. Kump. ‘Global Warming and the End-Permian Extinction Event: Proxy and Modeling Perspectives’. Earth-Science Reviews 149 (2015): 5–22. Web.
Darcy E. Ogden and Norman H. Sleep. ‘Explosive Eruption of Coal and Basalt and the End-Permian Mass Extinction’. Proceedings of the National Academy of Sciences of the United States of America 109.1 (2012): n. pag. Web. <https://www.jstor.org/stable/23076231?seq=1#metadata_info_tab_contents>.
---. ‘Explosive Eruption of Coal and Basalt and the End-Permian Mass Extinction’. Proceedings of the National Academy of Sciences of the United States of America 109.1 (2012): n. pag. Web. <https://www.jstor.org/stable/23076231?seq=1#metadata_info_tab_contents>.
D’Arrigo, Rosanne et al. ‘The Anomalous Winter of 1783-1784: Was the Laki Eruption or an Analog of the 2009-2010 Winter to Blame?’ Geophysical Research Letters 38.5 (2011): n/a-n/a. Web.
D’Arrigo, Rosanne, Rob Wilson, and Kevin J. Anchukaitis. ‘Volcanic Cooling Signal in Tree Ring Temperature Records for the Past Millennium’. Journal of Geophysical Research: Atmospheres 118.16 (2013): 9000–9010. Web.
De la Cruz-Reyna, Servando, and Robert I. Tilling. ‘Scientific and Public Responses to the Ongoing Volcanic Crisis at Popocatépetl Volcano, Mexico: Importance of an Effective Hazards-Warning System’. Journal of Volcanology and Geothermal Research 170.1–2 (2008): 121–134. Web.
‘Deccan Volcanism Caused Coupled pCO₂ and Terrestrial Temperature Rises, and Pre-Impact Extinctions in Northern China - Zhang et al., Accepted.Pdf’. Web. <http://eprints.whiterose.ac.uk/128432/1/Zhang%20et%20al.%2C%20accepted.pdf>.
Decker, Robert W., and Barbara Decker. Volcanoes. 3rd ed. New York: W. H. Freeman, 1998. Print.
Delos Reyes, Perla J. et al. ‘A Synthesis and Review of Historical Eruptions at Taal Volcano, Southern Luzon, Philippines’. Earth-Science Reviews 177 (2018): 565–588. Web.
Di Vito, Mauro A. et al. ‘Dynamics and Effects of the Vesuvius Pomici Di Avellino Plinian Eruption and Related Phenomena on the Bronze Age Landscape of Campania Region (Southern Italy)’. Quaternary International 499 (2019): 231–244. Web.
Dibben, Christopher, and David K Chester. ‘Human Vulnerability in Volcanic Environments: The Case of Furnas, São Miguel, Azores’. Journal of Volcanology and Geothermal Research 92.1–2 (1999): 133–150. Web.
Dogar, Muhammad Mubashar et al. ‘Sensitivity of the Regional Climate in the Middle East and North Africa to Volcanic Perturbations’. Journal of Geophysical Research: Atmospheres 122.15 (2017): 7922–7948. Web.
Driessen, Jan. ‘The Santorini Eruption. An Archaeological Investigation of Its Distal Impacts on Minoan Crete’. Quaternary International 499 (2019): 195–204. Web.
Dunbar, Nelia W. et al. ‘New Zealand Supereruption Provides Time Marker for the Last Glacial Maximum in Antarctica’. Scientific Reports 7.1 (2017): n. pag. Web.
‘Early to Late Maastrichtian Environmental Changes in the Indian Ocean Compared with Tethys and South Atlantic | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S003101821730069X?token=9E59368BF1A480D19C41B03216AE62CFB032CE517B33FD17B2D4C8AFC4CD0C3014B95F72AD1F4E87F5D05888E6623F45>.
‘Earth-Science Reviews’. 149 (2015): n. pag. Web. <https://www.sciencedirect.com/journal/earth-science-reviews/vol/149>.
‘Effects of Volcanic Air Pollution on Health’. N.p., n.d. Web. <https://www.researchgate.net/publication/12118448_Effects_of_volcanic_air_pollution_on_health>.
Ernst, Richard E., Kenneth L. Buchan, and Ian H. Campbell. ‘Frontiers in Large Igneous Province Research’. Lithos 79.3–4 (2005): 271–297. Web.
Ernst, Richard E., and Nasrrddine Youbi. ‘How Large Igneous Provinces Affect Global Climate, Sometimes Cause Mass Extinctions, and Represent Natural Markers in the Geological Record’. Palaeogeography, Palaeoclimatology, Palaeoecology 478 (2017): 30–52. Web.
---. ‘How Large Igneous Provinces Affect Global Climate, Sometimes Cause Mass Extinctions, and Represent Natural Markers in the Geological Record’. Palaeogeography, Palaeoclimatology, Palaeoecology 478 (2017): 30–52. Web.
‘Evidence of Cultural Responses to the Impact of the Mazama Ash Fall from Deeply Stratified Archaeological Sites in Southern Alberta, Canada | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618214005710?token=2963043EA7F872BCF96AAEA166AE865544D5787E1296D650809F7892FA0844B6E60DA91320E7AF252ADE63CD2B04B40D>.
‘Evidence-‐based Volcanology: Application to Eruption Crises’. Web. <http://www.geo.mtu.edu/~raman/VTimeSer/Bayesian_files/aspinall_etal_evidence_based_volcanology_application_eruption_crisis_Galeras.pdf>.
‘Expert Judgment and the Montserrat Volcano Eruption’. Web. <http://dutiosc.twi.tudelft.nl/~risk/extrafiles/EJcourse/Sheets/Aspinall%20&%20Cooke%20PSAM4%203-9.pdf>.
Fahrenkamp-Uppenbrink, Julia. ‘Preparing for the next Supereruption’. Science 363.6433 (2019): 1296.16-1298. Web.
Fantasia, Alicia et al. ‘Palaeoenvironmental Changes Associated with Deccan Volcanism, Examples from Terrestrial Deposits from Central India’. Palaeogeography, Palaeoclimatology, Palaeoecology 441 (2016): 165–180. Web.
Fearnley, C. J. et al. ‘Standardisation of the USGS Volcano Alert Level System (VALS): Analysis and Ramifications’. Bulletin of Volcanology 74.9 (2012): 2023–2036. Web.
Fearnley, Carina J. et al., eds. Observing the Volcano World: Volcano Crisis Communication. 1st ed. 2018. Cham: Springer International Publishing, 2018. Web. <http://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=3783283660002418&institutionId=2418&customerId=2415>.
Fedele, Francesco G. et al. ‘Ecosystem Impact of the Campanian Ignimbrite Eruption in Late Pleistocene Europe’. Quaternary Research 57.3 (2002): 420–424. Web.
Fedele, Francesco G., Biagio Giaccio, and Irka Hajdas. ‘Timescales and Cultural Process at 40,000BP in the Light of the Campanian Ignimbrite Eruption, Western Eurasia’. Journal of Human Evolution 55.5 (2008): 834–857. Web.
Fei, Jie, and Jie Zhou. ‘The Possible Climatic Impact in China of Iceland’s Eldgjá Eruption Inferred from Historical Sources’. Climatic Change 76.3–4 (2006): 443–457. Web.
---. ‘The Possible Climatic Impact in China of Iceland’s Eldgjá Eruption Inferred from Historical Sources’. Climatic Change 76.3–4 (2006): 443–457. Web.
Few, Roger, Maria Teresa Armijos, and Jenni Barclay. ‘Living with Volcan Tungurahua: The Dynamics of Vulnerability during Prolonged Volcanic Activity’. Geoforum 80 (2017): 72–81. Web.
---. ‘Living with Volcan Tungurahua: The Dynamics of Vulnerability during Prolonged Volcanic Activity’. Geoforum 80 (2017): 72–81. Web.
Firth, Callum R., and Bill McGuire. Volcanoes in the Quaternary. Geological Society special publication. London: Geological Society, 1999. Print.
Fitzsimmons, Kathryn E. et al. ‘The Campanian Ignimbrite Eruption: New Data on Volcanic Ash Dispersal and Its Potential Impact on Human Evolution’. PLoS ONE 8.6 (2013): n. pag. Web.
Flückiger, Simon et al. ‘Simulating Crop Yield Losses in Switzerland for Historical and Present Tambora Climate Scenarios’. Environmental Research Letters 12.7 (2017): n. pag. Web.
Francis, Peter, and Clive Oppenheimer. Volcanoes - 10 Copies in the Library. 2nd ed. Oxford: Oxford University Press, 2004. Print.
Franck Lavigne, Jean-Philippe Degeai, Jean-Christophe Komorowski, Sébastien Guillet, Vincent Robert, Pierre Lahitte, Clive Oppenheimer, Markus Stoffel, Céline M. Vidal, Surono, Indyo Pratomo, Patrick Wassmer, Irka Hajdas, Danang Sri Hadmoko and Edouard de Belizal. ‘Source of the Great A.D. 1257 Mystery Eruption Unveiled, Samalas Volcano, Rinjani Volcanic Complex, Indonesia’. Proceedings of the National Academy of Sciences of the United States of America 110.42 (2013): n. pag. Web. <https://www.jstor.org/stable/23750657?seq=1#metadata_info_tab_contents>.
Fraser, Nicholas C., and Hans-Dieter Sues. ‘The Beginning of the “Age of Dinosaurs”: A Brief Overview of Terrestrial Biotic Changes during the Triassic’. Earth and Environmental Science Transactions of the Royal Society of Edinburgh 101.3–4 (2010): 189–200. Web.
‘Gale General OneFile - Document - Air Pollution “Causes More Deaths than Smoking”’. N.p., n.d. Web. <https://go.gale.com/ps/i.do?&id=GALE|A578128317&v=2.1&u=uniaber&it=r&p=ITOF&sw=w>.
‘Gale General OneFile - Document - First Eyewitness Accounts of Mystery Volcanic Eruption’. N.p., n.d. Web. <https://go.gale.com/ps/i.do?&id=GALE|A383506238&v=2.1&u=uniaber&it=r&p=ITOF&sw=w>.
Gao, Chaochao et al. ‘Climatic Aftermath of the 1815 Tambora Eruption in China’. Journal of Meteorological Research 31.1 (2017): 28–38. Web.
Garcia Garriga, Joan, Kenneth Martínez Molina, and Javier Baena Preysler. ‘Neanderthal Survival in the North of the Iberian Peninsula? Reflections from a Catalan and Cantabrian Perspective’. Journal of World Prehistory 25.2 (2012): 81–121. Web.
Gertisser, R. ‘The Great 1815 Eruption of Tambora and Future Risks from Large-Scale Volcanism.(Report)’. Geology Today 31.4 (2012): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofa423720429&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,tambora&offset=0>.
Giuseppe Mastrolorenzo, Pierpaolo Petrone, Lucia Pappalardo and Michael F. Sheridan. ‘The Avellino 3780-Yr-B.P. Catastrophe as a Worst-Case Scenario for a Future Eruption at Vesuvius’. Proceedings of the National Academy of Sciences of the United States of America 103.12 (2006): n. pag. Web. <https://www.jstor.org/stable/30048947?seq=1#metadata_info_tab_contents>.
GLIKSON, A. ‘Asteroid/Comet Impact Clusters, Flood Basalts and Mass Extinctions: Significance of Isotopic Age Overlaps’. Earth and Planetary Science Letters 236.3–4 (2005): 933–937. Web.
Grasby, Stephen E. et al. ‘Mercury as a Proxy for Volcanic Emissions in the Geologic Record’. Earth-Science Reviews 196 (2019): n. pag. Web.
Grasby, Stephen E., Hamed Sanei, and Benoit Beauchamp. ‘Catastrophic Dispersion of Coal Fly Ash into Oceans during the Latest Permian Extinction’. Nature Geoscience 4.2 (2011): 104–107. Web.
Gräslund, BoPrice, Neil. ‘Twighlight of the Gods? The Dust Veil Event of AD 536 in Critical Perspective’. 86.2 428–443. Web. <https://search.proquest.com/docview/1021249071/9F226CEE94194FE3PQ/1?accountid=14783>.
Grattan, John. ‘Aspects of Armageddon: An Exploration of the Role of Volcanic Eruptions in Human History and Civilization’. Quaternary International 151.1 (2006): 10–18. Web.
---. ‘Pollution and Paradigms: Lessons from Icelandic Volcanism for Continental Flood Basalt Studies’. Lithos 79.3–4 (2005): 343–353. Web.
Grattan, John, Robin Torrence, and World Archaeological Congress. Living under the Shadow: Cultural Impacts of Volcanic Eruptions. Vol. 53. Walnut Creek, Calif: Left Coast Press, 2007. Web. <http://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=3794712070002418&institutionId=2418&customerId=2415>.
---. Living under the Shadow: Cultural Impacts of Volcanic Eruptions. Vol. 53. Walnut Creek, Calif: Left Coast Press, 2007. Web. <http://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=3735715500002418&institutionId=2418&customerId=2415>.
Grattan, J.P., and F.B. Pyatt. ‘Acid Damage to Vegetation Following the Laki Fissure Eruption in 1783 — an Historical Review’. Science of The Total Environment 151.3 (1994): 241–247. Web.
Gualda, Guilherme A. R., and Stephen R. Sutton. ‘The Year Leading to a Supereruption’. PLOS ONE 11.7 (2016): n. pag. Web.
Guillet, S. ‘Climate Response to the 1257 Samalas Eruption Revealed 1 by Proxy Records’. (2017): n. pag. Web. <https://www.repository.cam.ac.uk/handle/1810/262757>.
Gurioli, L. et al. ‘Pyroclastic Flow Hazard Assessment at Somma–Vesuvius Based on the Geological Record’. Bulletin of Volcanology 72.9 (2010): 1021–1038. Web.
H. Tuffen and R. Betts. ‘Volcanism and Climate: Chicken and Egg (or Vice Versa)?’ Philosophical Transactions: Mathematical, Physical and Engineering Sciences 368.1919 (2010): 2585–2588. Web. <http://www.jstor.org/stable/25753430>.
Haraldur Sigurdsson, Stanford Cashdollar and Stephen R. J. Sparks. ‘The Eruption of Vesuvius in A. D. 79: Reconstruction from Historical and Volcanological Evidence’. American Journal of Archaeology 86.1 (1982): 39–51. Web. <http://www.jstor.org/stable/504292>.
Harington, C. R. The Year without a Summer?: World Climate in 1816. Ottawa: Canadian Museum of Nature, 1992. Print.
Harris, Bethan. ‘The Potential Impact of Super-Volcanic Eruptions on the Earth’s Atmosphere’. Weather 63.8 (2008): 221–225. Web.
Hartmann, William K. et al. ‘Evidence for Recent Volcanism on Mars from Crater Counts’. Nature 397.6720 (1999): 586–589. Web.
Haslam, Michael et al. ‘The 74 Ka Toba Super-Eruption and Southern Indian Hominins: Archaeology, Lithic Technology and Environments at Jwalapuram Locality 3’. Journal of Archaeological Science 37.12 (2010): 3370–3384. Web.
Haslam, Michael, and Michael Petraglia. ‘Comment on "Environmental Impact of the 73ka Toba Super-Eruption in South Asia” by M.A.J. Williams, S.H. Ambrose, S. van Der Kaars, C. Ruehlemann, U. Chattopadhyaya, J. Pal and P.R. Chauhan [Palaeogeography, Palaeoclimatology, Palaeoecology 284 (2009) 295–314]’. Palaeogeography, Palaeoclimatology, Palaeoecology 296.1–2 (2010): 199–203. Web.
Haynes, Katharine, Jenni Barclay, and Nick Pidgeon. ‘The Issue of Trust and Its Influence on Risk Communication during a Volcanic Crisis’. Bulletin of Volcanology 70.5 (2008): 605–621. Web.
‘Hazard Information Management during the Autumn 2004 Reawakening of Mount St. Helens Volcano, Washington: Chapter 24 in A Volcano Rekindled: The Renewed Eruption of Mount St. Helens, 2004-2006’. N.p., n.d. Web. <http://pubs.er.usgs.gov/publication/pp175024>.
Head, James W. et al. ‘Venus Volcanism: Classification of Volcanic Features and Structures, Associations, and Global Distribution from Magellan Data’. Journal of Geophysical Research 97.E8 (1992): n. pag. Web.
‘Hints of a Volcanically Active Exomoon’. Space Daily (2011): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofg597833465&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,exo%20volcanism&offset=0>.
‘Historical Unrest at Large Calderas of the World’. N.p., n.d. Web. <http://pubs.er.usgs.gov/publication/b1855>.
Hizbaron, D.R. et al. ‘Towards Measurable Resilience: Mapping the Vulnerability of at-Risk Community at Kelud Volcano, Indonesia’. Applied Geography 97 (2018): 212–227. Web.
Hodel, F. et al. ‘Fossil Black Smoker Yields Oxygen Isotopic Composition of Neoproterozoic Seawater’. Nature Communications 9.1 (2018): n. pag. Web.
Hoffecker, John F. et al. ‘From the Bay of Naples to the River Don: The Campanian Ignimbrite Eruption and the Middle to Upper Paleolithic Transition in Eastern Europe’. Journal of Human Evolution 55.5 (2008): 858–870. Web.
Höskuldsson, Ármann et al. ‘The Millennium Eruption of Hekla in February 2000’. Bulletin of Volcanology 70.2 (2007): 169–182. Web.
Huang, Cy. ‘Cooling of the South China Sea by the Toba Eruption and Correlation with Other Climate Proxies Similar to 71,000 Years Ago’. Geophysical Research Letters 28.20 (2014): 3915–3918. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_wos000171588000023&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22toba%20eruption%22&offset=0>.
Hubbard, Zachary. ‘Paintings in the Year Without a Summer’. Philologia 11.1 (2019): n. pag. Web.
J. Lelieveld. ‘The Contribution of Outdoor Air Pollution Sources to Premature Mortality on a Global Scale’. Nature 525.7569 367–385. Web. <https://go.gale.com/ps/i.do?p=AONE&u=uniaber&id=GALE%7CA429410745&v=2.1&it=r>.
J. U. L. Baldini. ‘Evaluating the Link between the Sulfur-Rich Laacher See Volcanic Eruption and the Younger Dryas Climate Anomaly’. Climate of the Past 14 (2018): 969–990. Web. <https://doaj.org/article/c82dab44001c4b949ee409f70f257021>.
Jacoby, Gc. ‘Laki Eruption of 1783, Tree Rings, and Disaster for Northwest Alaska Inuit’. Quaternary Science Reviews 18.12 (1999): 1365–1371. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_wos000083568700004&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22laki%20eruption%22&offset=0>.
Joanna Slawinska. ‘Impact of Volcanic Eruptions on Decadal to Centennial Fluctuations of Arctic Sea Ice Extent during the Last Millennium and on Initiation of the Little Ice Age’. (2018): n. pag. Web. <https://journals.ametsoc.org/doi/full/10.1175/JCLI-D-16-0498.1>.
João Zilhão. ‘Neandertals and Moderns Mixed, and It Matters’. Evolutionary Anthropology: Issues, News, and Reviews 15.5 (2006): 183–195. Web. <https://onlinelibrary.wiley.com/doi/abs/10.1002/evan.20110>.
John Lowe, Nick Barton, Simon Blockley, Christopher Bronk Ramsey, Victoria L. Cullen, William Davies, Clive Gamble, Katharine Grant, Mark Hardiman, Rupert Housley, Christine S. Lane, Sharen Lee, Mark Lewis, Alison MacLeod, Martin Menzies, Wolfgang Müller, Mark Pollard, Catherine Price, Andrew P. Roberts, Eelco J. Rohling, Chris Satow, Victoria C. Smith, Chris B. Stringer, Emma L. Tomlinson, Dustin White, Paul Albert, Ilenia Arienzo, Graeme Barker, Dušan Borić, Antonio Carandente, Lucia Civetta, Catherine Ferrier, Jean-Luc Guadelli, Panagiotis Karkanas, Margarita Koumouzelis, Ulrich C. Müller, Giovanni Orsi, Jörg Pross, Mauro Rosi, Ljiljiana Shalamanov-Korobar, Nikolay Sirakov and Polychronis C. Tzedakis. ‘Volcanic Ash Layers Illuminate the Resilience of Neanderthals and Early Modern Humans to Natural Hazards’. Proceedings of the National Academy of Sciences of the United States of America 109.34 (2012): n. pag. Web. <https://www.jstor.org/stable/41700966?seq=1#metadata_info_tab_contents>.
Jón Steingrímsson. Fires of the Earth: The Laki Eruption, 1783-1784. Reykjavík: Nordic Volcanological Institute, 1998. Print.
---. Fires of the Earth: The Laki Eruption, 1783-1784. Reykjavík: Nordic Volcanological Institute, 1998. Print.
Jona Schellekens. ‘Irish Famines and English Mortality in the Eighteenth Century’. The Journal of Interdisciplinary History 27.1 29–43. Web. <https://go.gale.com/ps/i.do?&id=GALE|A18579104&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
Jonathan Stone. ‘Risk Reduction through Community-Based Monitoring: The Vigías of Tungurahua, Ecuador’. Journal of Applied Volcanology 3.1 (2014): n. pag. Web. <https://appliedvolc.biomedcentral.com/articles/10.1186/s13617-014-0011-9>.
Jones, Sacha Claire. ‘Palaeoenvironmental Response to the ∼74 Ka Toba Ash-Fall in the Jurreru and Middle Son Valleys in Southern and North-Central India’. Quaternary Research 73.2 (2010): 336–350. Web.
‘Journal of Volcanology and Geothermal Research: Special Issue on Sinabung and Kelud’. 382 (2019): n. pag. Web. <https://www.sciencedirect.com/journal/journal-of-volcanology-and-geothermal-research/vol/382/suppl/C>.
JUN SHEN, YONG LEI, THOMAS J. ALGEO, QINGLAI FENG, THOMAS SERVAIS, JIANXIN YU and LIAN ZHOU. ‘VOLCANIC EFFECTS ON MICROPLANKTON DURING THE PERMIAN-TRIASSIC TRANSITION (SHANGSI AND XINMIN, SOUTH CHINA)’. PALAIOS 28.7 (2013): n. pag. Web. <https://www.jstor.org/stable/43683731?seq=1#metadata_info_tab_contents>.
Kaltenegger, L., W. G. Henning, and D. D. Sasselov. ‘DETECTING VOLCANISM ON EXTRASOLAR PLANETS’. The Astronomical Journal 140.5 (2010): 1370–1380. Web.
Kandlbauer, J. et al. ‘Climate and Carbon Cycle Response to the 1815 Tambora Volcanic Eruption’. Journal of Geophysical Research: Atmospheres 118.22 (2013): 12,497-12,507. Web.
Kandlbauer, J., and R.S.J. Sparks. ‘New Estimates of the 1815 Tambora Eruption Volume’. Journal of Volcanology and Geothermal Research 286 (2014): 93–100. Web.
Kathryn E Fitzsimmons. ‘The Campanian Ignimbrite Eruption: New Data on Volcanic Ash Dispersal and Its Potential Impact on Human Evolution.’ PLoS ONE 8.6 (2013): n. pag. Web. <https://doaj.org/article/d962f3c36bb8435990b157d3376599d8>.
Keller, G. et al. ‘Deccan Volcanism Linked to the Cretaceous-Tertiary Boundary Mass Extinction: New Evidence from ONGC Wells in the Krishna-Godavari Basin’. Journal of the Geological Society of India 78.5 (2011): 399–428. Web.
Keller, G., A. Sahni, and S. Bajpai. ‘Deccan Volcanism, the KT Mass Extinction and Dinosaurs’. Journal of Biosciences 34.5 (2009): 709–728. Web.
Kent, Adam. ‘RESEARCH FOCUS: Tackling Supervolcanoes: Big and Fast?’ Geology 43.11 (2015): 1039–1040. Web.
Knappett, CarlRivers, RayEvans, Tim. ‘The Theran Eruption and Minoan Palatial Collapse’. 85.9 1008–1023. Web. <https://search.proquest.com/docview/896272713/fulltextPDF/3F1AFA67A52F429DPQ/1?accountid=14783>.
Künzler, Matthias, Christian Huggel, and Juan Manuel Ramírez. ‘A Risk Analysis for Floods and Lahars: Case Study in the Cordillera Central of Colombia’. Natural Hazards 64.1 (2012): 767–796. Web.
Lanciki, Alyson et al. ‘Sulfur Isotope Evidence of Little or No Stratospheric Impact by the 1783 Laki Volcanic Eruption’. Geophysical Research Letters 39.1 (2012): n/a-n/a. Web.
Lane, C. S., B. T. Chorn, and T. C. Johnson. ‘Ash from the Toba Supereruption in Lake Malawi Shows No Volcanic Winter in East Africa at 75 Ka’. Proceedings of the National Academy of Sciences 110.20 (2013): 8025–8029. Web.
Lane, Christine S. ‘Ash from the Toba Supereruption in Lake Malawi Shows No Volcanic Winter in East Africa at 75 Ka’. Proceedings of the National Academy of Sciences of the United States of America 110.20 (2013): 8025–8029. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_faoagrisUS201600137554&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22supereruption%22&offset=0>.
‘Late Pleistocene Human Population Bottlenecks, Volcanic Winter, and Differentiation of Modern Humans | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0047248498902196?token=7552FDE4AD153D8033B785131D7F8AC34E3E0ABA77DAB40EB3C9A449AD44583FDD787C3AF2592A72C48BA00A84A91473>.
Lawrence M. E. Percival, Micha Ruhl, Stephen P. Hesselbo, Hugh C. Jenkyns, Tamsin A. Mather and Jessica H. Whiteside. ‘Mercury Evidence for Pulsed Volcanism during the End-Triassic Mass Extinction’. Proceedings of the National Academy of Sciences of the United States of America 114.30 (2017): n. pag. Web. <https://www.jstor.org/stable/26486132?Search=yes&resultItemClick=true&&searchUri=%2Ftopic%2Fmass-extinction-events%2F%3FsearchType%3DfacetSearch%26amp%3Bsd%3D%26amp%3Bed%3D%26amp%3Brefreqid%3Dexcelsior%253A4c7a3104ad8fb89411b0d3db9f073dbe%26amp%3Bpagemark%3DcGFnZU1hcms9NA%253D%253D%26amp%3Btopic%3Dmass-extinction-events%26amp%3Ballow_empty_query%3DTrue&ab_segments=0%2Fbasic_SYC-5055%2Fcontrol&seq=1#metadata_info_tab_contents>.
Leonard, Graham S. et al. ‘Developing Effective Warning Systems: Ongoing Research at Ruapehu Volcano, New Zealand’. Journal of Volcanology and Geothermal Research 172.3–4 (2008): 199–215. Web.
‘Lessons from Recent Icelandic Eruptions’. Web. <https://www.chathamhouse.org/sites/default/files/public/Research/Energy,%20Environment%20and%20Development/r0112_highimpact.pdf>.
Lindström, Sofie et al. ‘Volcanic Mercury and Mutagenesis in Land Plants during the End-Triassic Mass Extinction’. Science Advances 5.10 (2019): n. pag. Web.
‘London’s Volcanic Winter - Current Archaeology’. N.p., n.d. Web. <https://www.archaeology.co.uk/articles/features/londons-volcanic-winter.htm>.
Longo, B.M., A. Rossignol, and J.B. Green. ‘Cardiorespiratory Health Effects Associated with Sulphurous Volcanic Air Pollution’. Public Health 122.8 (2008): 809–820. Web.
Lopes, Rosaly M.C. et al. ‘Beyond Earth: How Extra-Terrestrial Volcanism Has Changed Our Definition of a Volcano’. What Is a Volcano?. Special paper. Boulder, Colo: Geological Society of America. 11–30. Web. <http://specialpapers.gsapubs.org/lookup/doi/10.1130/2010.2470%2802%29>.
Lorenz, Stephan. ‘Exploring the Climate Response to the Tambora in 1815 and the 1809 Tropical Eruption’. Quaternary International 279–280 (2012): n. pag. Web.
Louys, Julien. ‘Mammal Community Structure of Sundanese Fossil Assemblages from the Late Pleistocene, and a Discussion on the Ecological Effects of the Toba Eruption’. Quaternary International 258 (2014): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofa285620234&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22toba%20eruption%22&offset=0>.
M. Damaschke,R. Sulpizio,G. Zanchetta,B. Wagner,N. Nowaczyk,J. Rethemeyer. ‘Tephrostratigraphic Studies on a Sediment Core from Lake Prespa in the Balkans’. Climate of the Past 9.1 (2013): 267–267. Web. <https://go.gale.com/ps/i.do?id=GALE%7CA481436213&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
Maltman, Chris, Graham Walter, and Vladimir Yurkov. ‘A Diverse Community of Metal(Loid) Oxide Respiring Bacteria Is Associated with Tube Worms in the Vicinity of the Juan de Fuca Ridge Black Smoker Field’. PLOS ONE 11.2 (2016): n. pag. Web.
Mannella, G. et al. ‘Palaeoenvironmental and Palaeohydrological Variability of Mountain Areas in the Central Mediterranean Region: A 190 Ka-Long Chronicle from the Independently Dated Fucino Palaeolake Record (Central Italy)’. Quaternary Science Reviews 210 (2019): 190–210. Web.
Manning, Joseph G. et al. ‘Volcanic Suppression of Nile Summer Flooding Triggers Revolt and Constrains Interstate Conflict in Ancient Egypt’. Nature Communications 8.1 (2017): n. pag. Web.
---. ‘Volcanic Suppression of Nile Summer Flooding Triggers Revolt and Constrains Interstate Conflict in Ancient Egypt’. Nature Communications 8.1 (2017): n. pag. Web.
Marshall, Lauren. ‘Multi-Model Comparison of the Volcanic Sulfate Deposition from the 1815 Eruption of Mt. Tambora’. Atmospheric Chemistry and Physics 18.3 2307–2328. Web. <https://www.atmos-chem-phys.net/18/2307/2018/>.
Martí, Joan, and Gerald Ernst. Volcanoes and the Environment. Cambridge: Cambridge University Press, 2005. Web. <http://www.vlebooks.com/vleweb/product/openreader?id=AberystUni&isbn=9780511331343>.
Mastin, Larry G., Alexa R. Van Eaton, and Jacob B. Lowenstern. ‘Modeling Ash Fall Distribution from a Yellowstone Supereruption’. Geochemistry, Geophysics, Geosystems 15.8 (2014): 3459–3475. Web.
Mastrolorenzo, G., and L. Pappalardo. ‘Hazard Assessment of Explosive Volcanism at Somma-Vesuvius’. Journal of Geophysical Research 115.B12 (2010): n. pag. Web.
Mastrolorenzo, Giuseppe et al. ‘The 472 AD Pollena Eruption of Somma-Vesuvius (Italy) and Its Environmental Impact at the End of the Roman Empire’. Journal of Volcanology and Geothermal Research 113.1–2 (2002): 19–36. Web.
Matthew Toohey. ‘Volcanic Stratospheric Sulfur Injections and Aerosol Optical Depth from 500 BCE to 1900 CE’. Earth System Science Data 9.2 809–809. Web. <https://go.gale.com/ps/i.do?&id=GALE|A513556448&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
McConnell, Joseph R. et al. ‘Synchronous Volcanic Eruptions and Abrupt Climate Change ∼17.7 Ka Plausibly Linked by Stratospheric Ozone Depletion’. Proceedings of the National Academy of Sciences 114.38 (2017): 10035–10040. Web.
McCoy, Floyd, and Grant Heiken. Volcanic Hazards and Disasters in Human Antiquity. Special paper / Geological Society of America. Boulder, Colo: Geological Society of America, 2000. Print.
McGuire, Bill. The Archaeology of Geological Catastrophes. Geological Society special publication. Bath: Geological Society, 2000. Print.
‘Medical Papyri Describe the Effects of the Santorinieruption on Human Health, and Date the Eruptionto August 1603–March 1601 BC’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0306987706005573?token=DAEB1FCD9B957C164CCFDE1E2DF78C6E4CCB706CF0CA20256DFBEEA257D11E5BFABC31BF10FD91E9032E5D494AC1EE0A>.
Meehl, Gerald A. et al. ‘Effects of the Mount Pinatubo Eruption on Decadal Climate Prediction Skill of Pacific Sea Surface Temperatures’. Geophysical Research Letters 42.24 (2015): 10,840-10,846. Web.
Mellars, Paul. ‘Neanderthals and the Modern Human Colonization of Europe’. Nature 432.7016 (2004): 461–465. Web.
---. ‘The Neanderthal Problem Continued’. Current Anthropology 40.3 (1999): 341–364. Web.
Michael Petraglia, Ravi Korisettar, Nicole Boivin, Christopher Clarkson, Peter Ditchfield, Sacha Jones, Jinu Koshy, Marta Mirazón Lahr, Clive Oppenheimer, David Pyle, Richard Roberts, Jean-Luc Schwenninger, Lee Arnold and Kevin White. ‘Middle Paleolithic Assemblages from the Indian Subcontinent before and after the Toba Super-Eruption’. Science 317.5834 (2007): n. pag. Web. <https://www.jstor.org/stable/20036656?seq=1#metadata_info_tab_contents>.
Michael R. Rampino and Stephen Self. ‘Bottleneck in Human Evolution and the Toba Eruption’. Science 262.5142 (1955): n. pag. Web. <https://www.jstor.org/stable/2882944?Search=yes&resultItemClick=true&searchText=no%3A5142&searchText=AND&searchText=sn%3A00368075&searchText=AND&searchText=sp%3A1955&searchText=AND&searchText=vo%3A262&searchText=AND&searchText=year%3A1993&searchUri=%2Faction%2FdoBasicSearch%3FQuery%3Dno%253A5142%2BAND%2Bsn%253A00368075%2BAND%2Bsp%253A1955%2BAND%2Bvo%253A262%2BAND%2Byear%253A1993%26amp%3Bymod%3DYour%2Binbound%2Blink%2Bdid%2Bnot%2Bhave%2Ban%2Bexact%2Bmatch%2Bin%2Bour%2Bdatabase.%2BBut%2Bbased%2Bon%2Bthe%2Belements%2Bwe%2Bcould%2Bmatch%252C%2Bwe%2Bhave%2Breturned%2Bthe%2Bfollowing%2Bresults.&ab_segments=0%2Fbasic_SYC-4946%2Fcontrol&refreqid=search-gateway%3A6e4dc1201cee6c8f7dab34dd5daf89e9&seq=1#metadata_info_tab_contents>.
Michael Staubwasser. ‘Impact of Climate Change on the Transition of Neanderthals to Modern Humans in Europe’. Proceedings of the National Academy of Sciences 115.37 (2018): 9116–9121. Web. <https://www.pnas.org/content/115/37/9116>.
Milia, Alfonsa, Arturo Raspini, and Maurizio M. Torrente. ‘The Dark Nature of Somma-Vesuvius Volcano: Evidence from the ∼3.5ka B.P. Avellino Eruption’. Quaternary International 173–174 (2007): 57–66. Web.
Miller, C. F., and D. A. Wark. ‘SUPERVOLCANOES AND THEIR EXPLOSIVE SUPERERUPTIONS’. Elements 4.1 (2008): 11–15. Web.
Miller, Gifford H. et al. ‘Abrupt Onset of the Little Ice Age Triggered by Volcanism and Sustained by Sea-Ice/Ocean Feedbacks’. Geophysical Research Letters 39.2 (2012): n/a-n/a. Web.
‘Modeling Cultural Responses to Volcanic Disaster in the Ancient Jama-Coaque Tradition, Coastal Ecuador: A Case Study in Cultural Collapse and Social Resilience | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618215008794?token=C280BD04B409C9B696DD4724F4EFBFC8BD31FD9BFFED653A8B81C65448BD2DD0D6031E8C65D26942772EC00E7E72596D>.
Monaghan, J.J., P.J. Bicknell, and R.J. Humble. ‘Volcanoes, Tsunamis and the Demise of the Minoans’. Physica D: Nonlinear Phenomena 77.1–3 (1994): 217–228. Web.
‘Monitoring, Forecasting Collapse Events, and Mapping Pyroclastic Deposits at Sinabung Volcano with Satellite Imagery | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0377027318301938?token=9E0D82814455B3D276499E8D54AA49CF5264293F6AD0E3761B96E54DA192B1C6C94BE8698A5DCC02708A72B314FF43DE>.
Muhammad Mubashar Dogar. ‘Ocean Sensitivity to Periodic and Constant Volcanism’. Scientific Reports 10.1 (2020): 1–15. Web. <https://doaj.org/article/905bab3aa68c4f97bbd9c963984ae3f1>.
‘Multiple Impacts across the Cretaceous–Tertiary Boundary’. Web. <http://geoweb.princeton.edu/research/Paleontology/Keller_et_al._ESR_03.pdf>.
‘Mystery Eruption Traced to Dangerous Italian Volcano : Research Highlights’. N.p., n.d. Web. <https://www.nature.com/articles/d41586-019-01462-6>.
Negi, J.G. et al. ‘A Possible K-T Boundary Bolide Impact Site Offshore near Bombay and Triggering of Rapid Deccan Volcanism’. Physics of the Earth and Planetary Interiors 76.3–4 (1993): 189–197. Web.
Newhall, C., and R. Hoblitt. ‘Constructing Event Trees for Volcanic Crises’. Bulletin of Volcanology 64.1 (2002): 3–20. Web.
Nicholas J. G. Pearce. ‘Origin of Ash in the Central Indian Ocean Basin and Its Implication for the Volume Estimate of the 74,000 Year BP Youngest Toba Eruption’. Current Science 889–893. Web. <https://pure.aber.ac.uk/portal/en/publications/origin-of-ash-in-the-central-indian-ocean-basin-and-its-implication-for-the-volume-estimate-of-the-74000-year-bp-youngest-toba-eruption(9a911aa8-2ae3-4edd-8c2f-bae37585268f).html>.
‘Non-Climatic Factors and the Environmental Impact of Volcanic Volatiles: Implications of the Laki Fissure Eruption of AD 1783’. N.p., n.d. Web. <https://www.researchgate.net/publication/249868764_Non-climatic_factors_and_the_environmental_impact_of_volcanic_volatiles_Implications_of_the_Laki_fissure_eruption_of_AD_1783>.
Olsson, J. et al. ‘Rapid Release of Metal Salts and Nutrients from the 2011 Grímsvötn, Iceland Volcanic Ash’. Geochimica et Cosmochimica Acta 123 (2013): 134–149. Web.
Oman, Luke et al. ‘High-Latitude Eruptions Cast Shadow over the African Monsoon and the Flow of the Nile’. Geophysical Research Letters 33.18 (2006): n/a-n/a. Web.
Oppenheimer, Clive. ‘Climatic, Environmental and Human Consequences of the Largest Known Historic Eruption: Tambora Volcano (Indonesia) 1815’. Progress in Physical Geography 27.2 (2003): 230–259. Web.
---. Eruptions That Shook the World. Cambridge: Cambridge University Press, 2011. Web. <http://www.vlebooks.com/vleweb/product/openreader?id=AberystUni&isbn=9781139111751>.
---. ‘Limited Global Change Due to the Largest Known Quaternary Eruption, Toba ≈74kyr BP?’ Quaternary Science Reviews 21.14–15 (2002): 1593–1609. Web.
Oppenheimer, Stephen. ‘A Single Southern Exit of Modern Humans from Africa: Before or after Toba?’ Quaternary International 258 (2012): 88–99. Web.
Panagiotakopulu, Eva et al. ‘Ancient Pests: The Season of the Santorini Minoan Volcanic Eruption and a Date from Insect Chitin’. Naturwissenschaften 100.7 (2013): 683–689. Web.
Paolo Cherubini. ‘The Olive-Branch Dating of the Santorini Eruption’. Antiquity 88.339 267–274. Web. <https://go.gale.com/ps/retrieve.do?tabID=T002&resultListType=RESULT_LIST&searchResultsType=SingleTab&searchType=AdvancedSearchForm&currentPosition=1&docId=GALE%7CA363102251&docType=Report&sort=RELEVANCE&contentSegment=ZONE-MOD1&prodId=AONE&contentSet=GALE%7CA363102251&searchId=R1&userGroupName=uniaber&inPS=true>.
Papale, Paolo. ‘Global Time-Size Distribution of Volcanic Eruptions on Earth’. Scientific Reports 8.1 (2018): n. pag. Web.
Papale, Paolo, and Warner Marzocchi. ‘Volcanic Threats to Global Society’. Science 363.6433 (2019): 1275–1276. Print.
Papale, Paolo, and John F. Shroder, eds. Volcanic Hazards, Risks and Disasters. Oxford: Elsevier, 2014. Web. <http://www.vlebooks.com/vleweb/product/openreader?id=AberystUni&isbn=9780123964762>.
Parnell, John. ‘Plate Tectonics and the Detection of Land-Based Biosignatures on Mars and Extrasolar Planets’. International Journal of Astrobiology 4.3–4 (2005): 175–186. Web.
Paul E. Olsen. ‘Giant Lava Flows, Mass Extinctions, and Mantle Plumes’. Science 284.5414 604–605. Web. <https://go.gale.com/ps/i.do?&id=GALE|A54552300&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
Paul Mellars. ‘The Earliest Modern Humans in Europe: The Reanalysis of Findings from Two Archaeological Sites Calls for a Reassessment of When Modern Humans Settled in Europe, and of Neanderthal Cultural Achievements’. Nature 479.7374 483–486. Web. <https://go.gale.com/ps/i.do?&id=GALE|A274027588&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
Paul Mellars and Jennifer C. French. ‘Tenfold Population Increase in Western Europe at the Neandertal—to—Modern Human Transition’. Science 333.6042 (2011): n. pag. Web. <https://www.jstor.org/stable/27978352?seq=1#metadata_info_tab_contents>.
Paul Mellars, Kevin C. Gori, Martin Carr, Pedro A. Soares and Martin B. Richards. ‘Genetic and Archaeological Perspectives on the Initial Modern Human Colonization of Southern Asia’. Proceedings of the National Academy of Sciences of the United States of America 110.26 (2013): n. pag. Web. <https://www.jstor.org/stable/42706546?seq=1#metadata_info_tab_contents>.
Pearson, Charlotte L. et al. ‘Annual Radiocarbon Record Indicates 16th Century BCE Date for the Thera Eruption’. Science Advances 4.8 (2018): n. pag. Web.
Percival, Lawrence M. E. et al. ‘Mercury Evidence for Pulsed Volcanism during the End-Triassic Mass Extinction’. Proceedings of the National Academy of Sciences 114.30 (2017): 7929–7934. Web.
Percival, L.M.E. et al. ‘Globally Enhanced Mercury Deposition during the End-Pliensbachian Extinction and Toarcian OAE: A Link to the Karoo–Ferrar Large Igneous Province’. Earth and Planetary Science Letters 428 (2015): 267–280. Web.
Periáñez, R., and J.M. Abril. ‘Modelling Tsunamis in the Eastern Mediterranean Sea. Application to the Minoan Santorini Tsunami Sequence as a Potential Scenario for the Biblical Exodus’. Journal of Marine Systems 139 (2014): 91–102. Web.
Petraglia , Michael D. ‘Toba Volcanic Super-Eruption, Environmental Change, and Hominin Occupation History in India over the Last 140,000 Years’. Quaternary international 258 (2014): 119–134. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_faoagrisUS201500210312&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22toba%20eruption%22&offset=0>.
Petraglia, Michael D. et al. ‘The Toba Volcanic Super-Eruption, Environmental Change, and Hominin Occupation History in India over the Last 140,000 Years’. Quaternary International 258 (2012): 119–134. Web.
Pfister, C. et al. ‘Winter Air Temperature Variations in Western Europe during the Early and High Middle Ages (AD 750–1300)’. The Holocene 8.5 (1998): 535–552. Web.
Pistolesi, Marco, Raffaello Cioni, Mauro Rosi, Katharine V. Cashman, et al. ‘Evidence for Lahar-Triggering Mechanisms in Complex Stratigraphic Sequences: The Post-Twelfth Century Eruptive Activity of Cotopaxi Volcano, Ecuador’. Bulletin of Volcanology 75.3 (2013): n. pag. Web.
Pistolesi, Marco, Raffaello Cioni, Mauro Rosi, and Eduardo Aguilera. ‘Lahar Hazard Assessment in the Southern Drainage System of Cotopaxi Volcano, Ecuador: Results from Multiscale Lahar Simulations’. Geomorphology 207 (2014): 51–63. Web.
---. ‘Lahar Hazard Assessment in the Southern Drainage System of Cotopaxi Volcano, Ecuador: Results from Multiscale Lahar Simulations’. Geomorphology 207 (2014): 51–63. Web.
‘Pollution and Paradigms: Lessons from Icelandic Volcanism for - Pollution and Paradigms1.Pdf’. N.p., n.d. Web. <http://cadair.aber.ac.uk/dspace/bitstream/handle/2160/234/Pollution%20and%20paradigms1.pdf?sequence=1>.
Ponomarenko, A. G. ‘Insects during the Time around the Permian—Triassic Crisis’. Paleontological Journal 50.2 (2016): 174–186. Web.
‘Prehistoric Human Responses to Volcanic Tephra Fall Events in the Ust-Kamchatsk Region, Kamchatka Peninsula (Kamchatsky Krai, Russian Federation) during the Middle to Late Holocene (6000-500 Cal BP) | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618215007090?token=5BC28A2B2576D0F5B208781B84A8A623845C2F735E442C62405C1B8234FC4D52B49F46FC00933D3242D0C641C1AA99E2>.
‘Preliminary Comparison of Ancient Bole Beds and Modern Soils Developed upon the Deccan Volcanic Basalts around Pune (India): Potential for Palaeoenvironmental Reconstruction’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618206001455?token=51068B2B3A216D1053DAF06EDA03B11F9254BA3DB2935BA4E0499B93AA5E346C44F82B2D1D119DBDBB3155E2A46E61D1>.
Pyle, David M. et al. ‘Wide Dispersal and Deposition of Distal Tephra during the Pleistocene “Campanian Ignimbrite/Y5” Eruption, Italy’. Quaternary Science Reviews 25.21–22 (2006): 2713–2728. Web.
‘Quaternary International’. 258 (2012): n. pag. Web. <https://www.sciencedirect.com/journal/quaternary-international/vol/258>.
Rampino, M. ‘Supereruptions as a Threat to Civilizations on Earth-like Planets’. Icarus 156.2 (2002): 562–569. Web.
Rampino, M R. ‘Bottleneck in Human Evolution and the Toba Eruption’. Science (New York 262.5142 (2014): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_medline8266085&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22toba%20eruption%22&offset=0>.
Rampino, M R, S Self, and R B Stothers. ‘Volcanic Winters’. Annual Review of Earth and Planetary Sciences 16.1 (1988): 73–99. Web.
Rampino, Michael R. ‘Relationship between Impact-Crater Size and Severity of Related Extinction Episodes’. Earth-Science Reviews 201 (2020): n. pag. Web.
Rampino, Michael R., and Stanley H. Ambrose. ‘Volcanic Winter in the Garden of Eden: The Toba Supereruption and the Late Pleistocene Human Population Crash’. Special Paper 345: Volcanic Hazards and Disasters in Human Antiquity. Vol. 345. Geological Society of America, 2000. 71–82. Web. <http://specialpapers.gsapubs.org/cgi/doi/10.1130/0-8137-2345-0.71>.
Rampino, Michael R., and Ken Caldeira. ‘Comparison of the Ages of Large-Body Impacts, Flood-Basalt Eruptions, Ocean-Anoxic Events and Extinctions over the Last 260 Million Years: A Statistical Study’. International Journal of Earth Sciences 107.2 (2018): 601–606. Web.
‘Recent Structural Evolution of the Cumbre Vieja Volcano, La Palma, Canary Islands: Volcanic Rift Zone Reconfiguration as a Precursor to Volcano Flank Instability’. Web. <http://www.geo.arizona.edu/~andyf/LaPalma/Rift%20Zone.pdf>.
‘Reconciling Multiple Ice-Core Volcanic Histories: The Potential of Tree-Ring and Documentary Evidence, 670-730 CE | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618215013464?token=C6435D598538AB261293887A9839D0F615EA3E661366B9746077BA40CE4E82A1CAE480BA177CF0EA3DA60D027BDE68F2>.
Reigstad, Laila Johanne et al. ‘Sulfur-Oxidizing Chemolithotrophic Proteobacteria Dominate the Microbiota in High Arctic Thermal Springs on Svalbard’. Astrobiology 11.7 (2011): 665–678. Web.
Richard Stone. ‘BACK FROM THE DEAD: The Once-Moribund Idea That Volcanism Helped Kill off the Dinosaurs Gains New Credibility’. Science 346.6215 (2014): n. pag. Web. <https://www.jstor.org/stable/24745481?Search=yes&resultItemClick=true&&searchUri=%2Ftopic%2Fmass-extinction-events%2F%3FsearchType%3DfacetSearch%26amp%3Bsd%3D%26amp%3Bed%3D%26amp%3Brefreqid%3Dexcelsior%253A4c7a3104ad8fb89411b0d3db9f073dbe%26amp%3Bpagemark%3DcGFnZU1hcms9Mw%253D%253D%26amp%3Btopic%3Dmass-extinction-events%26amp%3Ballow_empty_query%3DTrue&ab_segments=0%2Fbasic_SYC-5055%2Fcontrol&seq=1#metadata_info_tab_contents>.
Riede, Felix. ‘Doing Palaeo-Social Volcanology: Developing a Framework for Systematically Investigating the Impacts of Past Volcanic Eruptions on Human Societies Using Archaeological Datasets’. Quaternary International 499 (2019): 266–277. Web.
---. ‘Towards a Science of Past Disasters’. Natural Hazards 71.1 (2014): 335–362. Web.
Roberts, R. G., M. Storey, and M. Haslam. ‘Toba Supereruption: Age and Impact on East African Ecosystems’. Proceedings of the National Academy of Sciences 110.33 (2013): E3047–E3047. Web.
Robock, Alan. ‘Climatic Impact of Volcanic Emissions’. The State of the Planet: Frontiers and Challenges in Geophysics. [Place of publication not identified]: American Geophysical Union, 2004. 125–134. Web. <https://doi.org/10.1029/150GM11>.
---. ‘Did the Toba Volcanic Eruption of ∼74 Ka B.P. Produce Widespread Glaciation?’ Journal of Geophysical Research 114.D10 (2009): n. pag. Web.
---. ‘Volcanic Eruptions and Climate’. Reviews of Geophysics 38.2 (2000): 191–219. Web.
Rosi, Mauro, and Jay Hyams. Volcanoes. A Firefly guide. Toronto: Firefly Books, 2003. Print.
Rössler, Ole, and Stefan Brönnimann. ‘The Effect of the Tambora Eruption on Swiss Flood Generation in 1816/1817’. Science of The Total Environment 627 (2018): 1218–1227. Web.
Rothery, David A. Volcanoes, Earthquakes and Tsunamis. [New] ed. London: Teach Yourself, 2010. Web. <http://www.vlebooks.com/vleweb/product/openreader?id=AberystUni&isbn=9781444127416>.
Ryan C. Bay, Nathan Bramall and P. Buford Price. ‘Bipolar Correlation of Volcanism with Millennial Climate Change’. Proceedings of the National Academy of Sciences of the United States of America 101.17 (2004): n. pag. Web. <https://www.jstor.org/stable/3372084?seq=1#metadata_info_tab_contents>.
Sadler, J.P., and J.P. Grattan. ‘Volcanoes as Agents of Past Environmental Change’. Global and Planetary Change 21.1–3 (1999): 181–196. Web.
Sandri, Laura et al. ‘Long-Term Multi-Hazard Assessment for El Misti Volcano (Peru)’. Bulletin of Volcanology 76.2 (2014): n. pag. Web.
Saunders, A. D. ‘Large Igneous Provinces: Origin and Environmental Consequences’. Elements 1.5 (2005): 259–263. Web.
Scarth, Alwyn. Volcanoes: An Introduction. London: U C L Press, 1994. Print.
---. Vulcan’s Fury: Man against the Volcano. New Haven: Yale University Press, 1999. Print.
Schulte, P. et al. ‘The Chicxulub Asteroid Impact and Mass Extinction at the Cretaceous-Paleogene Boundary’. Science 327.5970 (2010): 1214–1218. Web.
Senatore, Maria Rosaria, Annamaria Ciarallo, and Jean-Daniel Stanley. ‘Pompeii Damaged by Volcaniclastic Debris Flows Triggered Centuries Prior to the 79 A.D. Vesuvius Eruption’. Geoarchaeology 29.1 (2014): 1–15. Web.
Shaw, Rajib, Juan M. Pulhin, and Joy Jacqueline Pereira. Climate Change Adaptation and Disaster Risk Reduction: An Asian Perspective, Vol. 5. 1st ed. v. 5. Bradford, U.K.: Emerald Group Pub. Ltd, 2010. Web. <http://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=4047952180002418&institutionId=2418&customerId=2415>.
Sigl, M. et al. ‘Timing and Climate Forcing of Volcanic Eruptions for the Past 2,500 Years’. Nature 523.7562 (2015): 543–549. Web.
Sigurdsson, Haraldur. Encyclopedia of Volcanoes. San Diego: Academic Press, 2000. Print.
‘Sinabung Volcano: How Culture Shapes Community Resilience’. N.p., n.d. Web. <https://www.emerald.com/insight/content/doi/10.1108/DPM-05-2018-0160/full/pdf?title=sinabung-volcano-how-culture-shapes-community-resilience>.
‘Six Medical Papyri Describe the Effect of Santorini’s Volcanic Ash’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0306987706000491?token=13233F3D8053237EAA0B5D4307D4EF02C39F56EAC3CF666212510A196E0D3ED2628EFCCD16403A858298DDD537A22B50>.
Smith, Eugene I. ‘Humans Thrived in South Africa through the Toba Eruption about 74,000 Years Ago.’ (2018): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_datacite15104146&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22toba%20eruption%22&offset=0>.
Smith, Eugene I. et al. ‘Humans Thrived in South Africa through the Toba Eruption about 74,000 Years Ago’. Nature 555.7697 (2018): 511–515. Web.
Sobolev, Stephan V. et al. ‘Linking Mantle Plumes, Large Igneous Provinces and Environmental Catastrophes’. Nature 477.7364 (2011): 312–316. Web.
---. ‘Linking Mantle Plumes, Large Igneous Provinces and Environmental Catastrophes’. Nature 477.7364 (2011): 312–316. Web.
‘Social Resilience and Long-Term Adaptation to Volcanic Disasters: The Archaeology of Continuity and Innovation in the Willaumez Peninsula, Papua New Guinea | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618214002535?token=BAEB0FFE44FA5EFE4CB35DA787B0AB116092B6A013138A4AF71E913F0DDC8C2D1065BD17188411ABC2C390212810942E>.
‘Social Responses to Volcanic Eruptions: A Review of Key Concepts | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618217315045?token=D8AE8C3A6359753D6D0FE577386A061826A84D07B8E6C82C0D1C416542362EBE8BEDAA531DDEE60B0A707677761F2FF5>.
Solikhin, Akhmad et al. ‘High-Spatial-Resolution Imagery Helps Map Deposits of the Large (VEI 4) 2010 Merapi Volcano Eruption and Their Impact’. Bulletin of Volcanology 77.3 (2015): n. pag. Web.
Sonnek, Karin Mossberg et al. ‘The Impacts of a Laki-like Eruption on the Present Swedish Society’. Natural Hazards 88.3 (2017): 1565–1590. Web.
Sparks, R. S. J., and W. P. Aspinall. ‘Volcanic Activity: Frontiers and Challenges in Forecasting, Prediction and Risk Assessment’. The State of the Planet: Frontiers and Challenges in Geophysics. Geophysical monograph. Washington, DC: American Geophysical Union, 2004. 359–373. Web. <https://doi.org/10.1029/150GM28>.
‘Speleothems as Sensitive Recorders of Volcanic Eruptions – the Bronze Age Minoan Eruption Recorded in a Stalagmite from Turkey | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0012821X14000570?token=2ABFE04AD3F8AB8DC1684D2DA9B5701D6D87666872A5151EB04D3C6DD789F7DAD3721FDAED98C0B86CCC361E9E92334D>.
Steven M. Holland. ‘Ecological Disruption Precedes Mass Extinction’. Proceedings of the National Academy of Sciences of the United States of America 113.30 (2016): n. pag. Web. <https://www.jstor.org/stable/26470935?Search=yes&resultItemClick=true&&searchUri=%2Ftopic%2Fmass-extinction-events%2F%3Frefreqid%3Dexcelsior%253A4c7a3104ad8fb89411b0d3db9f073dbe&ab_segments=0%2Fbasic_SYC-5055%2Fcontrol&seq=1#metadata_info_tab_contents>.
Stone, Richard. ‘Iceland’s Doomsday Scenario? The More Researchers Learn about the Unheralded Laki Eruption of 1783, the More They See a Need to Prepare for a Reprise That Could Include Fluoride Poisoning and Widespread Air Pollution.(News Focus)’. Science 306.5700 (2010): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofa126164075&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,%22laki%20eruption%22&offset=0>.
Stothers, Richard B. ‘The Great Tambora Eruption in 1815 and Its Aftermath’. Science 224 (2012): n. pag. Web. <https://whel-primo.hosted.exlibrisgroup.com/primo-explore/fulldisplay?docid=TN_gale_ofa3309276&context=PC&vid=44WHELF_ABW_VU1&lang=en_US&search_scope=Blended&adaptor=primo_central_multiple_fe&tab=blended&query=any,contains,tambora&offset=0>.
‘Stratospheric Ozone Destruction by the Bronze-Age Minoan Eruption (Santorini Volcano, Greece) - Srep12243.Pdf’. Web. <https://www.nature.com/articles/srep12243.pdf>.
Strom, Robert G., Gerald G. Schaber, and Douglas D. Dawson. ‘The Global Resurfacing of Venus’. Journal of Geophysical Research 99.E5 (1994): n. pag. Web.
Sturt W. Manning. ‘Dating the Thera (Santorini) Eruption: Archaeological and Scientific Evidence Supporting a High Chronology’. Antiquity 88.342 1164–1180. Web. <https://go.gale.com/ps/i.do?&id=GALE|A398627713&v=2.1&u=uniaber&it=r&p=AONE&sw=w>.
Sun, Chunqing et al. ‘Ash from Changbaishan Millennium Eruption Recorded in Greenland Ice: Implications for Determining the Eruption’s Timing and Impact’. Geophysical Research Letters 41.2 (2014): 694–701. Web.
Takehiro, Hayashi. ‘School-Community Collaboration in Disaster Education in a Primary School near Merapi Volcano in Java Island’. AIP Conference Proceedings. Author(s), 2016. Web. <http://aip.scitation.org/doi/abs/10.1063/1.4947418>.
Tandon, S.K. ‘Records of the Influence of Deccan Volcanism on Contemporary Sedimentary Environments in Central India’. Sedimentary Geology 147.1–2 (2002): 177–192. Web.
Tang, Qi et al. ‘Tropospheric Ozone Decrease Due to the Mount Pinatubo Eruption: Reduced Stratospheric Influx’. Geophysical Research Letters 40.20 (2013): 5553–5558. Web.
‘Tephra in Caves_ Distal Deposits of the Minoan Santorini Eruption and the Campanian Super-Eruption | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S104061821830483X?token=FF97A2D0F179AEA3E8E8909A3A8E38803125C16540DAB9417F1FA46681CADA03AD31278979F2E0840ADF2C84BD7788E0>.
‘---’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S104061821830483X?token=FF97A2D0F179AEA3E8E8909A3A8E38803125C16540DAB9417F1FA46681CADA03AD31278979F2E0840ADF2C84BD7788E0>.
‘Terrestrial Volcanism in Space and Time - Annual Review of Earth and Planetary Sciences, 21(1):427’. N.p., n.d. Web. <http://www.annualreviews.org/doi/abs/10.1146/annurev.ea.21.050193.002235>.
‘The ∼73 Ka Toba Super-Eruption and Its Impact: History of a Debate | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S104061821100485X?token=8BF1083F8D14FAB06C16D7C57DD08CEFAA3F7D958B6428004B30024D0B707C5E11140A670864D0A693B6714D582E784E>.
‘The Campanian Ignimbrite (Y5) Tephra at Crvena Stijena Rockshelter, Montenegro | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S0033589411000251?token=4E4EEC6191F39F42814BC42AAD9CF316D15FA910CEF7A1DE70CB8B236CE4BA69D520AD582BFAB2D648944AE366D7D6DD>.
‘The Drought and Locust Plague of 942-944 AD in the Yellow River Basin, China | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618214009215?token=95E82F06BE891AA37145B67D4A9B21F07267BC7E62AE025444E60286F4D9BB0BC9C7ED2CE641808B3AA00F62292967D1>.
‘The Economics of Natural Disasters - Cesifo-Forum-V11-Y2010-I2-P014-024.Pdf’. Web. <https://www.econstor.eu/bitstream/10419/166388/1/cesifo-forum-v11-y2010-i2-p014-024.pdf>.
‘The Effects of the Avellino Pumice Eruption on the Population of the Early Bronze Age Campanian Plain (Southern Italy) | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618218301228?token=79D7A12B29C1F81D9D3A0F58F90748B005D19DBD1698C5B59903C6A4FA58AAF79F27FA7FF61D9E3F4E5D31ACD812EFE4>.
‘The Timing and Spatiotemporal Patterning of Neanderthal Disappearance’. Nature 512.7514 306–310. Web. <https://go.gale.com/ps/i.do?p=AONE&u=uniaber&id=GALE|A379640969&v=2.1&it=r>.
Thordarson, Thorvaldur. ‘Atmospheric and Environmental Effects of the 1783–1784 Laki Eruption: A Review and Reassessment’. Journal of Geophysical Research 108.D1 (2003): n. pag. Web.
Thouret, J.-C. et al. ‘Toward a Revised Hazard Assessment at Merapi Volcano, Central Java’. Journal of Volcanology and Geothermal Research 100.1–4 (2000): 479–502. Web.
Tilling, Robert I., and Peter W. Lipman. ‘Lessons in Reducing Volcano Risk’. Nature 364.6435 (1993): 277–280. Web.
Tim Appenzeller. ‘Eastern Odyssey: Humans Had Spread across Asia by 50,000 Years Ago. Everything Else about Our Original Exodus from Africa Is up for Debate’. Nature 484.7396 24–27. Web. <https://go.gale.com/ps/retrieve.do?tabID=T002&resultListType=RESULT_LIST&searchResultsType=SingleTab&searchType=AdvancedSearchForm&currentPosition=2&docId=GALE%7CA289432159&docType=Article&sort=Relevance&contentSegment=ZONE-MOD1&prodId=AONE&contentSet=GALE%7CA289432159&searchId=R5&userGroupName=uniaber&inPS=true>.
Timmreck, C. ‘Modeling the Climatic Effects of Large Explosive Volcanic Eruptions’. Wiley Interdisciplinary Reviews: Climate Change 3.6 (2012): 545–564. Web.
Timmreck, Claudia et al. ‘Climate Response to the Toba Super-Eruption: Regional Changes’. Quaternary International 258 (2012): 30–44. Web.
Tom Simkin, Lee Siebert and Russell Blong. ‘Volcano Fatalities: Lessons from the Historical Record’. Science 291.5502 (2001): n. pag. Web. <https://www.jstor.org/stable/3082329?seq=1#metadata_info_tab_contents>.
Toohey, Matthew et al. ‘Climatic and Societal Impacts of a Volcanic Double Event at the Dawn of the Middle Ages’. Climatic Change 136.3–4 (2016): 401–412. Web.
Torrence, Robin. ‘Social Responses to Volcanic Eruptions: A Review of Key Concepts’. Quaternary International 499 (2019): 258–265. Web.
Torrence, Robin, and John Grattan. Natural Disasters and Cultural Change. One world archaeology. London: Routledge, 2002. Web. <http://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=3037246860002418&institutionId=2418&customerId=2415>.
---. Natural Disasters and Cultural Change. One world archaeology. London: Routledge, 2002. Web. <http://eu.alma.exlibrisgroup.com/view/action/uresolver.do?operation=resolveService&package_service_id=3037231330002418&institutionId=2418&customerId=2415>.
Trevisanato, Siro Igino. ‘Treatments for Burns in the London Medical Papyrus Show the First Seven Biblical Plagues of Egypt Are Coherent with Santorini’s Volcanic Fallout’. Medical Hypotheses 66.1 (2006): 193–196. Web.
---. ‘Treatments for Burns in the London Medical Papyrus Show the First Seven Biblical Plagues of Egypt Are Coherent with Santorini’s Volcanic Fallout’. Medical Hypotheses 66.1 (2006): 193–196. Web.
Trigo, Ricardo M., J. M. Vaquero, and R. B. Stothers. ‘Witnessing the Impact of the 1783–1784 Laki Eruption in the Southern Hemisphere’. Climatic Change 99.3–4 (2010): 535–546. Web.
‘Understanding the Environmental Impacts of Large Fissure Eruptions: Aerosol and Gas Emissions from the 2014–2015 Holuhraun Eruption (Iceland) - 1-S2.0-S0012821X17302911-Main.Pdf’. Web. <https://discovery.ucl.ac.uk/id/eprint/10074536/1/1-s2.0-S0012821X17302911-main.pdf>.
Vakulenko, N. V., and D. M. Sonechkin. ‘Analysis of Early Instrumental Air Temperature Observations before and after the Tambora Volcano Eruption’. Russian Meteorology and Hydrology 42.10 (2017): 677–684. Web.
VAN DE SCHOOTBRUGGE, BAS, and PAUL B. WIGNALL. ‘A Tale of Two Extinctions: Converging End-Permian and End-Triassic Scenarios’. Geological Magazine 153.2 (2016): 332–354. Web.
van Summeren, Joost, Clinton P. Conrad, and Eric Gaidos. ‘MANTLE CONVECTION, PLATE TECTONICS, AND VOLCANISM ON HOT EXO-EARTHS’. The Astrophysical Journal 736.1 (2011): n. pag. Web.
Veale, Lucy, and Georgina H Endfield. ‘Situating 1816, the “Year without Summer”, in the UK’. The Geographical Journal 182.4 (2016): 318–330. Web.
Vidal, Céline M. et al. ‘The 1257 Samalas Eruption (Lombok, Indonesia): The Single Greatest Stratospheric Gas Release of the Common Era’. Scientific Reports 6.1 (2016): n. pag. Web.
Villa, Paola et al. ‘From Neandertals to Modern Humans: New Data on the Uluzzian’. PLOS ONE 13.5 (2018): n. pag. Web.
‘Volcanic Activity and Human Society | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S1040618215008782?token=4BFF11422C65A4796BA4C9B85C94A0B7DE2CE3EC2872FBD9AED51E61C6AE30A06AEF7CA8BF529763A550F5028E303F01>.
‘Volcanic Disasters and Agricultural Intensification: A Case Study from the Willaumez Peninsula, Papua New Guinea | Elsevier Enhanced Reader’. n. pag. Web. <https://reader.elsevier.com/reader/sd/pii/S104061821100187X?token=957DD20CC0E7AB3C83F5CEA197075F2CFA510A05C918DD7CD29D1BC710AD7142C406CBEA0ED0B6CED53163B817079955>.
‘Volcanism and Tectonics on Venus’. Web. <http://www.es.ucsc.edu/~fnimmo/website/paper5.pdf>.
Wacey, David et al. ‘Geochemistry and Nano-Structure of a Putative ∼3240 Million-Year-Old Black Smoker Biota, Sulphur Springs Group, Western Australia’. Precambrian Research 249 (2014): 1–12. Web.
Wagner, B. et al. ‘Potential Impact of the 74 Ka Toba Eruption on the Balkan Region, SE Europe’. Climate of the Past Discussions 9.3 (2013): 3307–3319. Web.
---. ‘Potential Impact of the 74 Ka Toba Eruption on the Balkan Region, SE Europe’. Climate of the Past Discussions 9.3 (2013): 3307–3319. Web.
Walker, George P.L., Stephen Self, and Lionel Wilson. ‘Tarawera 1886, New Zealand — A Basaltic Plinian Fissure Eruption’. Journal of Volcanology and Geothermal Research 21.1–2 (1984): 61–78. Web.
Wignall, P. ‘The Link between Large Igneous Province Eruptions and Mass Extinctions’. Elements 1.5 (2005): 293–297. Web.
Wignall, P.B. ‘Large Igneous Provinces and Mass Extinctions’. Earth-Science Reviews 53.1–2 (2001): 1–33. Web.
Williams, Martin A.J., Stanley H. Ambrose, Sander van der Kaars, et al. ‘Environmental Impact of the 73ka Toba Super-Eruption in South Asia’. Palaeogeography, Palaeoclimatology, Palaeoecology 284.3–4 (2009): 295–314. Web.
Williams, Martin A.J., Stanley H. Ambrose, Sander van der Kaars, et al. ‘Reply to the Comment on "Environmental Impact of the 73ka Toba Super-Eruption in South Asia” by M. A. J. Williams, S. H. Ambrose, S. van Der Kaars, C. Ruehlemann, U. Chattopadhyaya, J. Pal, P. R. Chauhan [Palaeogeography, Palaeoclimatology, Palaeoecology 284 (2009) 295–314]’. Palaeogeography, Palaeoclimatology, Palaeoecology 296.1–2 (2010): 204–211. Web.
Wilson, Robert M. ‘Variation of Surface Air Temperatures in Relation to El Niño and Cataclysmic Volcanic Eruptions, 1796–1882’. Journal of Atmospheric and Solar-Terrestrial Physics 61.17 (1999): 1307–1319. Web.
Winchester, Simon. Krakatoa: The Day the World Exploded, 27 August 1883. London: Penguin Books, 2004. Print.
Witham, C. S., and C. Oppenheimer. ‘Mortality in England during the 1783?4 Laki Craters Eruption’. Bulletin of Volcanology 67.1 (2004): 15–26. Web.
Witham, C.S. ‘Volcanic Disasters and Incidents: A New Database’. Journal of Volcanology and Geothermal Research 148.3–4 (2005): 191–233. Web.
Woo, Judith Y. L., and Christopher R. J. Kilburn. ‘Intrusion and Deformation at Campi Flegrei, Southern Italy: Sills, Dikes, and Regional Extension’. Journal of Geophysical Research 115.B12 (2010): n. pag. Web.
Yadong Sun, Michael M. Joachimski, Paul B. Wignall, Chunbo Yan, Yanlong Chen, Haishui Jiang, Lina Wang and Xulong Lai. ‘Lethally Hot Temperatures During the Early Triassic Greenhouse’. Science 338.6105 (2012): n. pag. Web. <https://www.jstor.org/stable/41704126?seq=1#metadata_info_tab_contents>.
Yalcin, Kaplan et al. ‘Ice Core Evidence for a Second Volcanic Eruption around 1809 in the Northern Hemisphere’. Geophysical Research Letters 33.14 (2006): n. pag. Web.
YANG, ZHONGKANG et al. ‘A Great Volcanic Eruption around AD 1300 Recorded in Lacustrine Sediment from Dongdao Island, South China Sea’. Journal of Earth System Science 126.1 (2017): n. pag. Web.
Zambri, Brian et al. ‘Modeling the 1783–1784 Laki Eruption in Iceland: 1. Aerosol Evolution and Global Stratospheric Circulation Impacts’. Journal of Geophysical Research: Atmospheres (2019): n. pag. Web.
---. ‘Modeling the 1783–1784 Laki Eruption in Iceland: 2. Climate Impacts’. Journal of Geophysical Research: Atmospheres (2019): n. pag. Web.
Zanchetta, Giovanni et al. ‘Tephrostratigraphy of Paleoclimatic Archives in Central Mediterranean during the Bronze Age’. Quaternary International 499 (2019): 186–194. Web.
