Publications List Search Advanced Filters Author - Any -TestH. F. AasD.S. AbbotAnne-Sofie AhmA-S.C. AhmM. AleneE.W. AlexanderA. AndersT AndersonJ.K. AnsongE. AntillaB.K. ArbicY. AshkenazyJ. AustermannS.M. AwramikJ-R. BahamondeN BasovaR. BeachE.A. BellD.I. BennH BentheY BerkmenS BernasconiT. BerquóM. BizzarroC.J. BjerrumS. Blanco-FerreraS. BluherD.H. BoggsU. BoldKyle BonickiC.S. BorlinaT. BosakK BoseS.A. BowringE. BoyleJ.J. BrocksS.D. BurgessC.C. CalmetA. CampionC.Y. ChenDaniele CherniakR. CoeP.A. CohenD. CondonJ. ConnellyB. CornuelleF.A. CorsettiJ.M. CottleG.M. CoxE. CrawfordJ.R. CrevelingP.W. CrockfordJ.L. CrowleyH. DaherT. DahlH. DangCurtis DeutschCurtis DeutschE. DomackY. DonnadieuAlexander DregerF.Ö. DudásT Dvoretskova VBlake DyerB. DyerM.P. EddyStacey EdmonsondI. EisenmanJ.F. EisnsleD.H. ErwinD.A.D. EvansR.C. EwingAthena EysterI.J. FairchildJ. FeinbergL. FernándezD. FerreiraD.A. FikeW.W. FischerRuth FongO. FringerR.R. FuI. Garrick-BethellM. GebreslassieA. GetraerE.C. GeymanEmily GeymanEmily GeymanB.C. GillB. GiritL. GodfreyJ.C. GoodmanD GreenwoodJ. GrotzingerG HaberlandC.J. HagenB. HaileabKarl HallgrenG.P. HalversonV. HanusP.M. HarrisR.J. HarrisonT.M. HarrisonJoe HaumacherC.C. HayC. HayesW HendricksonJohn HigginsJ.A. HigginsP.F. HoffmanM. HofmannBolton HowesB. HowesM. HuberM.T. HurtgenJ.M. HussonJon HussonP. HuybersO IsaacA. IshidaAkizumi IshidaM.F. JansenG.R.T. JenkinD.T. JohnstonD.S. JonesJ.A. KaandorpJaap KaandorpZ KaganT. KeelerK.W. KellersonJ. KelloggNigel KellyT. KillianH.M. KirkpatrickJ.L. KirschvinkK. KitajimaKouki KitajimaJ. KohlerT KoivulaM KoivusaloR.E. KoppV KotsjurubaA. KouchinskyM. KunzmannM. LambA LandeK. LatychevH.C.P. LauG. Le HirK. LewisD. LiC LimE.A. LimaU. LinnemannB. LinzmeierBenjamin LinzmeierS. LockK.L. LouzadaG.D. LoveS. LuckA. LukyanovF.A. MacdonaldS.A. MacLennanA MakarAdam MaloofAdam MaloofA.C. MaloofAdam MaloofAdam MaloofA.C. MaloofRyan ManzukR.A. ManzukRyan ManzukRyan ManzukJ MarniemiCraig MartinJ.A. Mattias GreenM. MazouadDavid McGeeD. McGeeK McMartinJ MegermanA.K. MehraAkshay MehraD. MenemenlisO. Merino-ToméA.J. MerschatSenne MichielssenR. MitchellJ.X. MitrovicaStephen MojzsisJ.L. MooreS. MukhopadhyayM. MüllerR MurphyA MusjalkovskajaMatthew NadeauC.Z. NashClaire NicholsF NuttallS. OleynikSergey OleynikM. OppenheimerM PaleseIndu PanigrahiY. ParkM ParkkiC.A. PartinS. PedersenS. PetersShanan PetersD. PierceG. PoirierL. PoppickS.M. PorterP.M. PoussartD.S. PowarsT PozdnjakovaC. ProistosescuD ProtvinSam PurkisS.J. PurkisR.H. RainbirdJ. RamezaniJ. RamezaniG. RamsteinT.D. RaubA.H.N. RiceM. RomalisA. RooneyC.F. RootsC.V. RoseB.E.J. RoseR RoskoskiL RoskoskiW. RozenP.M. SadlerBradley SamuelsB.M. SamuelsJ. Sanz-LópezR SarmaM. SchindeleggerM.D. SchmitzA SchmoldtB. SchoeneBlair SchoeneD.P. SchragD. SchumannC. Scott SouthworthF.J. SimonsE SinelnikovaDevdigvijay SinghT SlotkinS.A. SouleAlex SpatzierS.T. StewartDaniel StolperJ.V. StraussN.L. Swanson-HysellN. TailbyA TanF. TangA. Tasistro-HartR.J.M. TaylorT TephlyT. TesemaK ThiemerD. TrailM.M. TremblayAndrew TurnerAndrew TurnerE. TzipermanT UgarovaH. ValiJ. ValleyJohn ValleyL ValzelliW.J.J. van PeltV VinogradovaA. VoigtK WardS.G. WarrenBruce WatsonE.B. Bruce WatsonW.A. WattersM. WebsterM. WebsterMark WebsterBenjamin WeissB.P. WeissM.M. WielickiJulia WilcotsJ.G. WilliamsB. WouterZiman WuNan YaoN. YaoMike ZawaskiW. Zhang Type - Any -ArtworkJournal ArticleMiscellaneousPatent Year - Any -202420232022202120202019201820172016201520142013201220112010200920082007200620052004200320022001200019991996 Keyword - Any -aeolianaerosolsAlice Springs orogenyalkalinityAnthropoceneantiparallel remanenceapparent polar wander (APW)archaeocyatharchaeocyath; biodiversity; Cambrian; coral; ecosystem engineering; paleoenvironment; reef; sponge; three-dimensionalasteroidsastrochronologyAustraliaBahamasbathymetrybiodiversitybiogenic magnetiteBitter Springs FormationCC isotopesCa and Mg isotopesCa isotopesCA-ID-TIMSCA-ID-TIMS U-Pb analysesCambrianCantabrian Zonecap carbonatecap dolostonecarbon cycleCarbon isotopesCarbonatecarbonate cyclescarbonate platformcarbonate sedimentcarbonate sedimentologyCarbonatesCarboniferousChemostratigraphic correlationchemostratigraphyclassificationclimatecoralcorecraterCryogeniancyclescyclostratigraphydetrital zirconsdiagenesisearly EarthEarth rotationEarth-Moon historyecosystem engineeringEdiacaranEdiacaran Earth historyexchange couplingferromagnetic resonancegeodynamogeomagnetic polarity time scalegeomorphologygiant ooidsglacial isostatic adjustmentGlaciationGlacioeustasyGreat Bahama BankGreat BasinhabitabilityHadean earthHelderberg Grouphelium isotopeshematiteHidden Markov modelsHolocenehotspotice wedgesimage processingimpactimpact cratersimpact-generated fieldsIsostasyIsotope stratigraphyJack HillsKeweenawan RiftKlonk EventLake BonnevilleLake LahontanLandsatlandscape evolutionlast interglacial periodLate Paleozoic Ice AgeLaurentiaLaurentide ice sheetLittle Ice AgeLonarLonar craterLunar orbitmachine learningMackenzie Mountains Supergroupmagnetofossilsmagnetotactic bacteriamantle viscosityMarinoanMarlboro ClayMarsmartiteMATLABmelt rocksmeteoric diagenesisMg isotopesMilankovitchmineral dustMoonmorphological analysisNeoproterozoicNuccaleena Formationobliquity of the eclipticOcean tidesooidooidsooliteorbital tuningoxygen isotopesPaleocene-Eocene thermal maximumpaleoclimatePaleoclimatologypaleoenvironmentpaleogeographypaleointensitypaleomagnetismPaleoshorelinesparasequenceperiglacialperiglacial featurespermafrostplate tectonicsreconstructionRedox proxiesreefremanent magnetizationremote sensingrock magnetismRodiniarunoff erosionsatelliteSeawaterseawater chemistrysedimentary faciessedimentary magnetismsedimentologyself-reversalserial sectioningShaler SupergroupshockShorelinesShuram excursionSIMSSnowball Earthsoftwarespectral analysisspherulesspongeSr isotopesSr/SrStill water levelStratigraphystream geometrystream networkStrontium isotopesSvalbardthorium isotopesthree-dimensionaltidal channeltidal flattidestime seriesTPWTrezona excursionTrezona Formationtrue polar wander (TPW)U–Pb geochronologyVictoria IslandWater depth Publications Category - Any -Cenozoic AnalogsExtreme Negative Carbon-Isotope AnomaliesImpact CratersSea Level during the Last Interglacial PeriodSnowball Earth HypothesisThe Atomic MagnetometerThe Cambrian ExplosionThe Geometry of Earth's Magnetic FieldTrue Polar Wander AuthorTitleTypeYear #ABCDEFGHIJKLMNOPQRSTUVWXYZ 88 Publications # Maloof A. 1996. "Journal of Glaciology" cover photograph. :Journal of Glaciology, Volume 42. Referenced from www.cambridge.org: "Journal of Glaciology" cover photograph. A Kopp R, Schumann D, Raub T, Powars D, Godfrey L, Swanson-Hysell N, Maloof A, Vali H. 2009. An Appalachian Amazon? Magnetofossil evidence for the development of a tropical river-like system in the mid-Atlantic United States during the Paleocene-Eocene thermal maximum. Paleoceanography. 24(4). Referenced from doi.org: An Appalachian Amazon? Magnetofossil evidence for the development of a tropical river-like system in the mid-Atlantic United States during the Paleocene-Eocene thermal maximum. 16maloof.pdf Samuels B, Kellerson K, Girit B, Lukyanov A, Maloof A, Rozen W. 2016. Apparatuses and methods for serial sectioning and imaging. Referenced from patents.google.com: Apparatuses and methods for serial sectioning and imaging. 48maloof.pdf MacLennan S, Park Y, Swanson-Hysell N, Maloof A, Schoene B, Gebreslassie M, Antilla E, Tesema T, Alene M, Haileab B. 2018. The arc of the Snowball: U-Pb dates constrain the Islay anomaly and the initiation of the Sturtian glaciation. Geology. 46(6):539–542. doi:10.1130/G40171.1. Referenced from doi.org: The arc of the Snowball: U-Pb dates constrain the Islay anomaly and the initiation of the Sturtian glaciation. 55maloof.pdf Tasistro-Hart A, Maloof A, Schoene B, Eddy M. 2020. Astronomically forced hydrology of the Late Cretaceous sub-tropical Potosí Basin, Bolivia. GSA Bulletin. 132(9-10):1931–1952. doi:10.1130/B35189.1. Referenced from doi.org: Astronomically forced hydrology of the Late Cretaceous sub-tropical Potosí Basin, Bolivia. 71maloof.pdf Dahl T, Connelly J, Li D, Kouchinsky A, Gill B, Porter S, Maloof A, Bizzarro M. 2019. Atmosphere–ocean oxygen and productivity dynamics during early animal radiations. Proceedings of the National Academy of Sciences.:201901178. doi:10.1073/pnas.1901178116. Referenced from doi.org: Atmosphere–ocean oxygen and productivity dynamics during early animal radiations. 62maloof.pdf B Manzuk RA, Maloof AC, Kaandorp JA, Webster M. 2022. Branching archaeocyaths as ecosystem engineers during the Cambrian radiation. Geobiology. 00:1– 20. doi:10.1111/gbi.12521. Referenced from onlinelibrary.wiley.com: Branching archaeocyaths as ecosystem engineers during the Cambrian radiation. 80maloof.pdf C Husson J, Higgins J, Maloof A, Schoene B. 2015. Ca and Mg isotope constraints on the origin of Earth’s deepest δ13C excursion. Geochimica et Cosmochimica Acta. 160:243–266. doi:10.1016/j.gca.2015.03.012. Referenced from doi.org: Ca and Mg isotope constraints on the origin of Earth’s deepest δ13C excursion. 44maloof.pdf Ahm A-S, Bjerrum C, Hoffman P, Macdonald F, Maloof A, Rose C, Strauss J, Higgins J. 2021. The Ca and Mg isotope record of the Cryogenian Trezona carbon isotope excursion. Earth and Planetary Science Letters. 568:117002. doi:10.1016/j.epsl.2021.117002. Referenced from doi.org: The Ca and Mg isotope record of the Cryogenian Trezona carbon isotope excursion. 76maloof.pdf Macdonald F, Schmitz M, Crowley J, Roots C, Jones D, Maloof A, Strauss J, Cohen P, Johnston D, Schrag D. 2010. Calibrating the Cryogenian. Science. 327(5970):1241. doi:10.1126/science.1183325. Referenced from doi.org: Calibrating the Cryogenian. 19maloof.pdf Kopp R, Weiss B, Maloof A, Vali H, Nash C, Kirschvink J. 2006. Chains, clumps, and strings: Magnetofossil taphonomy with ferromagnetic resonance spectroscopy. Earth and Planetary Science Letters. 247(1):10–25. doi:10.1016/j.epsl.2006.05.001. Referenced from doi.org: Chains, clumps, and strings: Magnetofossil taphonomy with ferromagnetic resonance spectroscopy. 10maloof.pdf Moore J, Porter S, Webster M, Maloof A. 2019. Chancelloriid sclerites from the Dyeran–Delamaran (‘Lower–Middle’ Cambrian) boundary interval of the Pioche–Caliente region, Nevada, USA. Papers on Palaeontology. doi:10.1002/spp2.1274. Referenced from onlinelibrary.wiley.com: Chancelloriid sclerites from the Dyeran–Delamaran (‘Lower–Middle’ Cambrian) boundary interval of the Pioche–Caliente region, Nevada, USA. 64maloof Husson J, Schoene B, Bluher S, Maloof A. 2016. Chemostratigraphic and U–Pb geochronologic constraints on carbon cycling across the Silurian–Devonian boundary. Earth and Planetary Science Letters. 436:108–120. doi:10.1016/j.epsl.2015.11.044. Referenced from doi.org: Chemostratigraphic and U–Pb geochronologic constraints on carbon cycling across the Silurian–Devonian boundary. 47maloof.pdf Getraer A, Maloof A. 2021. Climate-Driven Variability in Runoff Erosion Encoded in Stream Network Geometry. Geophys Res Lett. 48(3):e2020GL091777. doi:10.1029/2020GL091777. Referenced from doi.org: Climate-Driven Variability in Runoff Erosion Encoded in Stream Network Geometry. 72maloof.pdf Maloof A, Halverson G, Kirschvink J, Schrag D, Weiss B, Hoffman P. 2006. Combined paleomagnetic, isotopic, and stratigraphic evidence for true polar wander from the Neoproterozoic Akademikerbreen Group, Svalbard, Norway. GSA Bulletin. 118(9-10):1099–1124. doi:10.1130/B25892.1. Referenced from doi.org: Combined paleomagnetic, isotopic, and stratigraphic evidence for true polar wander from the Neoproterozoic Akademikerbreen Group, Svalbard, Norway. 09maloof.pdf Corsetti F, Awramik S, Pierce D. 2003. Comment on: A complex microbiota from snowball Earth times: Microfossils from the Neoproterozoic Kingston Peak Formation, Death Valley, USA. Proceedings of the National Academy of Sciences. 100(8):4399–4404. doi:10.1073/pnas.0730560100. Referenced from doi.org: Comment on: A complex microbiota from snowball Earth times: Microfossils from the Neoproterozoic Kingston Peak Formation, Death Valley, USA. 05maloof.pdf Campion A, Maloof A, Schoene B, Oleynik S, Sanz-López J, Blanco-Ferrera S, Merino-Tomé O, Bahamonde J-R, Fernández L. 2018. Constraining the Timing and Amplitude of Early Serpukhovian Glacioeustasy With a Continuous Carbonate Record in Northern Spain. Geochem. Geophys. Geosyst. 19(8):2647–2660. doi:10.1029/2017GC007369. Referenced from doi.org: Constraining the Timing and Amplitude of Early Serpukhovian Glacioeustasy With a Continuous Carbonate Record in Northern Spain. 57maloof.pdf Maloof A, Ramezani J, Bowring S, Fike D, Porter S, Mazouad M. 2010. Constraints on early Cambrian carbon cycling from the duration of the Nemakit-Daldynian–Tommotian boundary δ13C shift, Morocco. Geology. 38(7):623–626. doi:10.1130/G30726.1. Referenced from doi.org: Constraints on early Cambrian carbon cycling from the duration of the Nemakit-Daldynian–Tommotian boundary δ13C shift, Morocco. 22maloof.pdf Austermann J, Chen C, Lau H, Maloof A, Latychev K. 2020. Constraints on mantle viscosity and Laurentide ice sheet evolution from pluvial paleolake shorelines in the western United States. Earth and Planetary Science Letters. 532:116006. doi:10.1016/j.epsl.2019.116006. Referenced from escholarship.org: Constraints on mantle viscosity and Laurentide ice sheet evolution from pluvial paleolake shorelines in the western United States. 70maloof.pdf Swanson-Hysell N, Maloof A, Kirschvink J, Evans D, Halverson G, Hurtgen M. 2012. Constraints on Neoproterozoic paleogeography and Paleozoic orogenesis from paleomagnetic records of the Bitter Springs Formation, Amadeus Basin, central Australia. American Journal of Science. 312:817–884. doi:10.2475/08.2012.01. Referenced from doi.org: Constraints on Neoproterozoic paleogeography and Paleozoic orogenesis from paleomagnetic records of the Bitter Springs Formation, Amadeus Basin, central Australia. 36maloof.pdf Rose C, Swanson-Hysell N, Husson J, Poppick L, Cottle J, Schoene B, Maloof A. 2012. Constraints on the origin and relative timing of the Trezona δ13C anomaly below the end-Cryogenian glaciation. Earth and Planetary Science Letters. 319-320:241–250. doi:10.1016/j.epsl.2011.12.027. Referenced from doi.org: Constraints on the origin and relative timing of the Trezona δ13C anomaly below the end-Cryogenian glaciation. 31maloof.pdf Swanson-Hysell N, Rose C, Calmet C, Halverson G, Hurtgen M, Maloof A. 2010. Cryogenian Glaciation and the Onset of Carbon-Isotope Decoupling. Science. 328(5978):608. doi:10.1126/science.1184508. Referenced from science.sciencemag.org: Cryogenian Glaciation and the Onset of Carbon-Isotope Decoupling. 21maloof.pdf Hoffman P, Halverson G, Domack E, Maloof A, Swanson-Hysell N, Cox G. 2012. Cryogenian glaciations on the southern tropical paleomargin of Laurentia (NE Svalbard and East Greenland), and a primary origin for the upper Russøya (Islay) carbon isotope excursion. Precambrian Research. s 206–207:137 – 158. doi:10.1016/j.precamres.2012.02.018. Referenced from doi.org: Cryogenian glaciations on the southern tropical paleomargin of Laurentia (NE Svalbard and East Greenland), and a primary origin for the upper Russøya (Islay) carbon isotope excursion. 34maloof.pdf D Geyman E, Maloof A. 2020. Deriving tidal structure from satellite image time series. Earth and Space Science. 7:e2019EA000958. doi:10.1029/2019EA000958. Referenced from doi.org: Deriving tidal structure from satellite image time series. 69maloof.pdf Geyman E, Maloof A. 2019. A diurnal carbon engine explains 13C-enriched carbonates without increasing the global production of oxygen. Proceedings of the National Academy of Sciences.:201908783. doi:10.1073/pnas.1908783116. Referenced from doi.org: A diurnal carbon engine explains 13C-enriched carbonates without increasing the global production of oxygen. 63maloof.pdf E Maloof A, Porter S, Moore J, Dudás F, Bowring S, Higgins J, Fike D, Eddy M. 2010. The earliest Cambrian record of animals and ocean geochemical change. GSA Bulletin. 122(11-12):1731–1774. doi:10.1130/B30346.1. Referenced from doi.org: The earliest Cambrian record of animals and ocean geochemical change. 27maloof.pdf Ahm A-S, Maloof A, Macdonald F, Hoffman P, Bjerrum C, Bold U, Rose C, Strauss J, Higgins J. 2019. An early diagenetic deglacial origin for basal Ediacaran “cap dolostones”. Earth and Planetary Science Letters. 506:292–307. doi:10.1016/j.epsl.2018.10.046. Referenced from doi.org: An early diagenetic deglacial origin for basal Ediacaran “cap dolostones”. 58maloof.pdf Rose C, Maloof A, Schoene B, Ewing R, Linnemann U, Hofmann M, Cottle J. 2013. The End-Cryogenian Glaciation of South Australia. Geoscience Canada. 40(4):256–293. doi:10.12789/geocanj.2013.40.019. Referenced from doi.org: The End-Cryogenian Glaciation of South Australia. 38maloof.pdf Halverson G, Dudás F, Maloof A, Bowring S. 2007. Evolution of the 87Sr/86Sr composition of Neoproterozoic seawater. Neoproterozoic to Paleozoic Ocean Chemistry. 256(3):103–129. doi:10.1016/j.palaeo.2007.02.028. Referenced from doi.org: Evolution of the 87Sr/86Sr composition of Neoproterozoic seawater. 13maloof.pdf Maloof A, Schrag D, Crowley J, Bowring S. 2005. An expanded record of Early Cambrian carbon cycling from the Anti-Atlas Margin, Morocco. Canadian Journal of Earth Sciences. 42(12):2195–2216. doi:10.1139/e05-062. Referenced from doi.org: An expanded record of Early Cambrian carbon cycling from the Anti-Atlas Margin, Morocco. 07maloof.pdf F Geyman E, Maloof A. 2021. Facies control on carbonate δ13C on the Great Bahama Bank. Geology. 49(9):1049–1054. doi:10.1130/G48862.1. Referenced from doi.org: Facies control on carbonate δ13C on the Great Bahama Bank. 75maloof.pdf G MacLennan S, Eddy M, Merschat A, Mehra A, Crockford P, Maloof A, Scott Southworth C, Schoene B. 2020. Geologic evidence for an icehouse Earth before the Sturtian global glaciation. Science Advances. 6(24). doi:10.1126/sciadv.aay6647. Referenced from doi.org: Geologic evidence for an icehouse Earth before the Sturtian global glaciation. 68maloof.pdf Maloof A, Stewart S, Weiss B, Soule S, Swanson-Hysell N, Louzada K, Garrick-Bethell I, Poussart P. 2010. Geology of Lonar Crater, India. GSA Bulletin. 122(1-2):109–126. doi:10.1130/B26474.1. Referenced from doi.org: Geology of Lonar Crater, India. 18maloof.pdf Dyer B, Maloof A, Higgins J. 2015. Glacioeustasy, meteoric diagenesis, and the carbon cycle during the Middle Carboniferous. Geochem. Geophys. Geosyst. 16(10):3383–3399. doi:10.1002/2015GC006002. Referenced from doi.org: Glacioeustasy, meteoric diagenesis, and the carbon cycle during the Middle Carboniferous. 46maloof.pdf H Hayes C, McGee D, Mukhopadhyay S, Boyle E, Maloof A. 2017. Helium and thorium isotope constraints on African dust transport to the Bahamas over recent millennia. Earth and Planetary Science Letters. 457:385–394. doi:10.1016/j.epsl.2016.10.031. Referenced from doi.org: Helium and thorium isotope constraints on African dust transport to the Bahamas over recent millennia. 49maloof.pdf Manzuk R, Singh D, Mehra A, Geyman E, Edmonsond S, Maloof A. 2022. A High-Resolution Multispectral Macro-Imager for Geology and Paleontology. GSA Today. 32. doi:10.1130/gsatg533a.1. Referenced from doi.org: A High-Resolution Multispectral Macro-Imager for Geology and Paleontology. 79maloof.pdf Geyman E, van Pelt W, Maloof A, Aas HF, Kohler J. 2022. Historical glacier change on Svalbard predicts doubling of mass loss by 2100. Nature. 601(7893):374–379. doi:10.1038/s41586-021-04314-4. Referenced from doi.org: Historical glacier change on Svalbard predicts doubling of mass loss by 2100. 78maloof.pdf Maloof A, Grotzinger J. 2012. The Holocene shallowing-upward parasequence of north-west Andros Island, Bahamas. Sedimentology. 59(4):1375 – 1407. Referenced from doi.org: The Holocene shallowing-upward parasequence of north-west Andros Island, Bahamas. 32maloof.pdf Geyman E, Maloof A, Dyer B. 2021. How is sea level change encoded in carbonate stratigraphy?. Earth and Planetary Science Letters. 560:116790. doi:10.1016/j.epsl.2021.116790. Referenced from www.sciencedirect.com: How is sea level change encoded in carbonate stratigraphy?. 73maloof.pdf I Panigrahi I, Manzuk R, Maloof A, Fong R. 2023. Improving Data-Efficient Fossil Segmentation via Model Editing. 83maloof.pdf L Husson JM, Linzmeier BJ, Kitajima K, Ishida A, Maloof AC, Schoene B, Peters SE, Valley JW. 2020. Large isotopic variability at the micron-scale in ‘Shuram’ excursion carbonates from South Australia. Earth and Planetary Science Letters. 538:116211. doi:10.1016/j.epsl.2020.116211. Referenced from www.sciencedirect.com: Large isotopic variability at the micron-scale in ‘Shuram’ excursion carbonates from South Australia. 66maloof.pdf Park Y, Swanson-Hysell N, MacLennan S, Maloof A, Gebreslassie M, Tremblay M, Schoene B, Alene M, Antilla E, Tesema T, et al. 2019. The lead-up to the Sturtian Snowball Earth: Neoproterozoic chemostratigraphy time-calibrated by the Tambien Group of Ethiopia. GSA Bulletin. 132(5-6):1119–1149. doi:10.1130/B35178.1. Referenced from doi.org: The lead-up to the Sturtian Snowball Earth: Neoproterozoic chemostratigraphy time-calibrated by the Tambien Group of Ethiopia. 61maloof Hay C, Creveling J, Hagen C, Maloof A, Huybers P. 2019. A library of early Cambrian chemostratigraphic correlations from a reproducible algorithm. Geology. 47(5):457–460. doi:10.1130/G46019.1. Referenced from doi.org: A library of early Cambrian chemostratigraphic correlations from a reproducible algorithm. 60maloof.pdf Daher H, Arbic B, Williams J, Ansong J, Boggs D, Müller M, Schindelegger M, Austermann J, Cornuelle B, Crawford E, et al. 2021. Long-term Earth-Moon evolution with high-level orbit and ocean tide models. Journal of Geophysical Research: Planets.:e2021JE006875. doi:10.1029/2021JE006875. Referenced from doi.org: Long-term Earth-Moon evolution with high-level orbit and ocean tide models. 77maloof.pdf M Swanson-Hysell N, Burgess S, Maloof A, Bowring S. 2014. Magmatic activity and plate motion during the latent stage of Midcontinent Rift development. Geology. 42(6):475–478. doi:10.1130/G35271.1. Referenced from doi.org: Magmatic activity and plate motion during the latent stage of Midcontinent Rift development. 39maloof.pdf Halverson G, Maloof A, Hoffman P. 2004. The Marinoan glaciation (Neoproterozoic) in northeast Svalbard. Basin Research. 16(3):297–324. doi:10.1111/j.1365-2117.2004.00234.x. Referenced from doi.org: The Marinoan glaciation (Neoproterozoic) in northeast Svalbard. 06maloof.pdf Mehra A, Maloof A. 2018. A multiscale approach reveals that Cloudina aggregates are detritus and not in situ reef constructions. Proceedings of the National Academy of Sciences. 115(11):E2519 - E2527. doi:10.1073/pnas.1719911115. Referenced from doi.org: A multiscale approach reveals that Cloudina aggregates are detritus and not in situ reef constructions. 54maloof.pdf N Maloof A, Kellogg J, Anders A. 2002. Neoproterozoic sand wedges: crack formation in frozen soils under diurnal forcing during a snowball Earth. Earth and Planetary Science Letters. 204(1):1–15. doi:10.1016/S0012-821X(02)00960-3. Referenced from doi.org: Neoproterozoic sand wedges: crack formation in frozen soils under diurnal forcing during a snowball Earth. 04maloof.pdf Ewing R, Eisenman I, Lamb M, Poppick L, Maloof A, Fischer W. 2014. New constraints on equatorial temperatures during a Late Neoproterozoic snowball Earth glaciation. Earth and Planetary Science Letters. 406:110–122. doi:10.1016/j.epsl.2014.09.017. Referenced from doi.org: New constraints on equatorial temperatures during a Late Neoproterozoic snowball Earth glaciation. 40maloof.pdf Lewis K, Keeler T, Maloof A. 2011. New Software for Plotting and Analyzing Stratigraphic Data. Eos Trans. AGU. 92(5):37–38. doi:10.1029/2011EO050002. Referenced from doi.org: New Software for Plotting and Analyzing Stratigraphic Data. 28maloof.pdf Pagination Current page 1 Page 2 Next page Next › Last page Last »