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Stromboli, Italy
Official, Figure in a journal article
(a) Map of the dNBR obtained using the NBR indexes from the Sentinel-2 images acquired on 22 May and 1 June 2022; (b) cumulative probability of combustion given by 100-run numerical simulations
Figure 9 in: Guardo, R., Bilotta, G., Ganci, G., Zuccarello, F., Andronico, D., & Cappello, A. (2024). Modeling Fire Hazards Induced by Volcanic Eruptions: The Case of Stromboli (Italy). Fire, 7(3), 70.

Stromboli, Italy
Official, Figure in a journal article
(a) Map of the dNBR obtained using the NBR indexes from the Sentinel-2 images acquired on 2 and 7 July 2019; (b) cumulative probability of combustion given by 100-run numerical simulations
Figure 7 in: Guardo, R., Bilotta, G., Ganci, G., Zuccarello, F., Andronico, D., & Cappello, A. (2024). Modeling Fire Hazards Induced by Volcanic Eruptions: The Case of Stromboli (Italy). Fire, 7(3), 70.

Mayon, Philippines
Official, Map sheet or poster
2018 Mayon Volcano Lahar Hazard Map
Philippine Institute of Volcanology and Seismology (PHIVOLCS). (2018). 2018 Mayon Volcano Lahar Hazard Map.

Auckland Volcanic Field, New Zealand
Figure in a journal article
24-h averages of SO2 concentration over Auckland in Domain 4, from 0–100 m above ground level at a 500-m resolution
Figure 8 in: Brody-Heine, S., Katurji, M., Stewart, C., Wilson, T., Smid, E. R., & Trancoso, R. (2024). Modeling SO2 dispersion from future eruptions in the Auckland Volcanic Field, New Zealand. Journal of Applied Volcanology, 13(1), 1-18.

Pelée, Martinique [France]
Figure in a journal article
5% probability maps for selected scenarios
Figure 7 in: Michaud-Dubuy, A., Carazzo, G., & Kaminski, E. (2021). Volcanic hazard assessment for tephra fallout in Martinique. Journal of Applied Volcanology, 10(1), 1-20. https://doi.org/10.1186/s13617-021-00106-7.

Holuhraun (Askja) & Bárdarbunga, Iceland
Official, Map in an information statement
Á litaða svæðinu eru líkur á gasmengun frá eldgosinu. Fim 18 Sep.
(In the colored area there is a likelihood of gas pollution from the eruption. Thu 18 Sep.)
Iceland Meteorological Office (IMO). (2014). Á litaða svæðinu eru líkur á gasmengun frá eldgosinu. Fim 18 Sep.

Okataina, New Zealand
Official, Figure in hazard assessment
A map of the possible distribution of a future rhyolite pyroclastic fall deposit from the Okataina Centre, based on past eruption deposits
Figure 11 in: Nairn, I.A. (1993). Volcanic hazards at Okataina Centre. 3rd ed. Ministry of Civil Defence, Palmerston North, NZ. Volcanic hazards information series 2. 29 p. Reproduced on website: https://www.gns.cri.nz/Home/Learning/Science-Topics/Volcanoes/New-Zealand-Volcanoes/Volcano-Geology-and-Hazards/Okataina-Volcanic-Centre-Geology

Popocatépetl, Mexico
Official, Figure in hazard assessment
a) Mapa de las zonas afectadas por las avalanchas de escombros DAD1 o Tlayecac Inferior (>50,000 años A.P.; zona I) y DAD2 o Tlayecac superior (~23,500 años A.P.; zona 2) y de una nueva posible área de afectación (zona III); b) Mapa de peligros por avalanchas de escombros: en color amarillo se señala el área que podría ser ocupada parcialmente por una futura avalancha de escombros
(a) Map of the areas affected by debris avalanches DAD1 or Lower Tlayecac (>50,000 years BP; zone I) and DAD2 or Upper Tlayecac (~23,500 years BP; zone 2) and of a new possible area of affectation (zone III ); b) Debris avalanche hazard map: yellow indicates the area that could be partially occupied by a future debris avalanche)
Figure 129 in: Martin Del Pozzo, A.L, Alatorre Ibargüengoitia M., Arana Salinas L., Bonasia R., Capra Pedol L., Cassata W., Cordoba G., Cortés Ramos J., Delgado Granados H., Ferrés López M.D., Fonseca Álvarez R., García Reynoso J.A., Gisbert G., Guerrero López D.A., Jaimes Viera M., Macías Vázquez J.L., Nieto Obregon J., Nieto Torres A., Paredes Ruiz P.A., Portocarrero Martínez J., Renne P., Rodríguez Espinosa D.M., Salinas Sánchez S., Siebe Grabach C., & Tellez Ugalde E. (2017). Estudios geológicos y actualización del mapa de peligros del volcán Popocatépetl. Memoria técnica del mapa de peligros del volcán Popocatépetl. Instituto de Geofísica, Universidad Nacional Autónoma de México (UNAM).

Ruapehu, New Zealand
Figure in a journal article
Absolute probability for areas to be affected by a ballistic impact density >0.001
Figure 12 in: Strehlow, K., Sandri, L., Gottsmann, J. H., Kilgour, G., Rust, A. C., & Tonini, R. (2017). Phreatic eruptions at crater lakes: occurrence statistics and probabilistic hazard forecast. Journal of Applied Volcanology, 6(1), 4. https://doi.org/10.1186/s13617-016-0053-2

Irazú, Costa Rica
Figure in a journal article
Accumulated ash fallout probability and mass
Figure 3 in: Barrantes, G., Núñez, S., & Malavassi, E. (2018). Ash fallout hazard from Irazú volcano, Costa Rica. Revista Geográfica de Chile Terra Australis, 54(1), 13-25. https://doi.org/10.23854/07199562.2018541Barrantes13

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Access or danger zone
Acid rain
Ash-cloud surges
Ballistics
Caldera-formation hazards
Debris avalanches
Deformation hazards
Distal hazards
Earthquakes
Explosion hazards, unspecific
Fire
Floods or jokulhaups
Flowage hazards
Gas
Geothermal hazards
Lahars
Landslides
Lateral or directed blasts
Lava dome-related hazards
Lava flows
Laze
Lightning
Littoral blasts
PDCs
Proximal hazards
Regional hazards
Rockfalls
Sedimentation or erosion
Shockwaves
Surges
Tephra fall
Tsunami
Unstated or all hazards
Vent-opening hazards
Vog
Water disturbances or marine hazards

AERMOD
ASH3D
ASHFALL
Ballista
Ballistics
BET_VH
CALPUFF
DAMBRK
DOWNFLOW
Eject!
Energy cone or line
ERN-Volcano
Etna Lava Flow Model
FALL3D
Flexpart
FLO-2D
FLOW
FLOW2D or FLOW3D
FLOWGO
G-EVER VHASS
Generic buffer model
Generic probability distribution model
Generic spatial density model
Generic/unknown KDE vent-opening model
Great Balls of Fire
HASSET
HAZMAP
HEC-RAS
HIMAT-FAO
HYDESim
HYDRAUX
Hysplit
Info layer weighting model
LaharFlow
LAHARZ
LavaC
LavaPL
LavaSIM
LAZSLO
Limit Equilibrium Analysis
Lines of Steepest Descent
LPAC
MAGFLOW
MatHaz
MOLASSES
MrLavaLoba
MULTIFLOW
MultiHaz lahar model
NAME
Peak Ground Acceleration model
Prandl-Meyer shockwave model
PUFF
PyF
PYROFLOW
PYROFLOW ash-cloud surge model
Q-LavHa
QVAST
SCIARA-fv2
SLAG
Tephra2
TephraProb
TITAN2D
TWODEE-2
Unknown flood model
Unknown flow model
Unknown gas dispersion model
Unknown lahar flow model
Unknown lava flow model
Unknown tephra model
Unnamed ballistic model [Alatorre-Ibargüengoitia & Delgado-Granados (2006)]
Unnamed ballistic model [Alatorre-Ibargüengoitia et al. (2012)]
Unnamed ballistic model [Instituto Geológico y Minero de España (2006)]
Unnamed ballistic model [Nurmawati & Konstantinou (2018)]
Unnamed Bayesian fault vent-opening model [Bevilacqua et al. (2017)]
Unnamed Bayesian KDE vent-opening model [Bevilacqua et al. (2017)]
Unnamed cellular automata lava flow model [Miyamoto & Sasaki (1997)]
Unnamed cellular automata PDC model [Kelfoun et al. 1995]
Unnamed cost-distance model [Barrantes Castillo & Malavassi Rojas (2015)]
Unnamed Cox process model [Diggle & Milne (1983)]
Unnamed ellipse tephra model [Blong (1981)]
Unnamed empirical altitude-length lava flow model
Unnamed empirical area-volume relationship
Unnamed empirical column height-thickness model [Carey & Sparks (1986)]
Unnamed empirical tephra fallout model
Unnamed empirical tephra model [Bertin et al. (2019)]
Unnamed energy cone model [Toyos et al. (2007)]
Unnamed GIS watershed/lavashed model [Kauahikaua et al. (1998)]
Unnamed KDE SAMSE vent-opening model [Connor et al. (2012)]
Unnamed KDE vent-opening model [Connor & Connor (2009)]
Unnamed lahar model [Kuniaki & Ido (2003)]
Unnamed lahar model [Miyamoto & Ito (2003)]
Unnamed lahar travel time model [Pierson (1998)]
Unnamed lava flow model [Cabildo Tenerife (2012)]
Unnamed lava flow model [CAPRA]
Unnamed lava flow model [Marrero et al. (2019)]
Unnamed lava flow model [Miyamoto & Sasaki (1998)]
Unnamed lava flow model [Yamashita (1990)]
Unnamed mass flow model [Mastrolorenzo & Pappalardo (2010)]
Unnamed mass flow model [Yamashita & Miyamoto (1991)]
Unnamed particle sedimentation model [Rossi et al. 2019]
Unnamed shockwave model [Córdoba & Del Risco (1998)]
Unnamed tephra model [Folch & Felpeto (2005)]
Unnamed tephra model [Hoblitt et al. (1987); Hoblitt & Scott (2011)]
Unnamed tephra model [JMA]
Unnamed tephra model [Mastrolorenzo & Pappalardo (2010)]
Unnamed tephra model [Pasquill (1974)]
Unnamed tephra model [Shaw et al. (1974)]
Unnamed tephra model [Suzuki (1985)]
Unnamed topographic lava flow model
Unnamed vent-opening model [Becerril et al. (2013)]
Unnamed weighted avg. vent-opening model [Bevilacqua et al. (2017)]
VAFTAD
Vent Opening Probability
VIGIL
VOL-CALPUFF
VolcFire
VolcFlow
VORIS

Arrival time
Ballistic impact density
Ballistic impact energy
Concentration/Density
Crater diameter
Exposure or susceptibility metric
Factor of Safety
Footprint of inundation
Grain size (isopleth)
Impact, severity, or damage metric
Loading
Magnitude
Mass
Model start locations
Number of events/year
Number of simulations
Peak ground acceleration
pH
Pressure or overpressure
Probability of exceeding a persistence/duration threshold
Probability of exceeding an arrival time threshold
Probability of exceeding concentration threshold
Probability of exceeding impact density threshold
Probability of exceeding impact energy threshold
Probability of exceeding load threshold
Probability of exceeding thickness threshold
Probability of inundation
Probability/susceptibility of vent opening
Risk metric
Spatial density
Symbols, arrows, or lines
Text description of hazard location
Text only
Thickness (isopach)
Thickness and grain size (combined)
Velocity
Volume
Whole map
Wind rose

Caldera
Complex
Compound
Cone
Crater rows
Explosion crater
Fissure vent
Lava cone
Lava dome
Maar
Pyroclastic cone
Pyroclastic shield
Shield
Stratovolcano
Subglacial
Submarine
Tuff cone
Tuff ring
Tuya
Unknown
Volcanic field
Volcanic remnant