New Mexico Geology 69 Verplanck, P.L., Van Gosen, B.S., Seal, R.R, and McCafferty, A.E., 2014, A deposit model for carbonatite and peralkaline intrusion-related rare earth element deposits: U.S. Geological Survey Scientific Investigations Report 2010–5070-J, 58 pp. Woolley, A. R. and Kempe, D.R.C., 1989, Carbonatites: Nomenclature, average chemical compositions and element distribution; in Bell, K., ed., Carbonatites: Genesis and Evolution: Unwin Hyman, London, pp. 1–14. Zech, R. S., Reynolds, R. L., Rosenbaum, J. G., and Brownfield, I. K., 1994, Heavy-mineral placer deposits of the Ute Mountain Ute Indian Reservation, southwestern Colorado and northwestern New Mexico: U.S. Geological Survey, Bulletin 2061-B, 39 pp. Circular 2, 15 pp. Sherer, R. L., 1990, Pajarito yttrium-zirconium deposit, Otero County, New Mexico: New Mexico Geology, v. 12, p. 21. Singer, D. A., 2000, Descriptive model of carbonatite deposits; in USGS Mineral Deposit Models: U.S. Geological Survey, Digital Data Series DDS-064, model 10, 3 pp. Staatz, M. H., 2000, Descriptive model of thorium-rare-earth veins; in USGS Mineral Deposit Models: U.S. Geological Survey, Digital Data Series DDS-064, model 11d, 6 pp. Taylor, S. R., and McClennan, S.M., 1985, The Continental Crust; its composition and evolution: Blackwell Science Publishers, Oxford, 312 pp. USGS, 2015, Mineral commodity summaries: U.S. Geological Survey, 196 pp. Vance, Z., 2013, Mineralogy, Geochemistry and Genesis of the Hydrothermal REE-Fluroite-AG-PB-CU Ore Deposits of the Gallinas Mountains, New Mexico [M.S. thesis]: Socorro, New Mexico Institute of Mining and Technology, 219 pp.
69 Verplanck, P.L, Van Gosen, B.S, Seal, r.r., McCafferty, A.E, 2014,碳酸盐岩和过碱性侵入体相关稀土元素矿床的沉积模式:美国地质调查科学调查报告2010-5070-J, 58 pp. Woolley, A. R., 1989,碳酸盐岩:命名、平均化学成分和元素分布;在贝尔,K.编,碳酸盐岩:成因和演化:Unwin Hyman,伦敦,第1-14页。Zech, R. S., Reynolds, R. L., Rosenbaum, J. G.和Brownfield, I. K., 1994,科罗拉多西南部和新墨西哥州西北部尤特山尤特印第安保留区的重矿物砂矿:美国地质调查局,公告2061-B, 39页。通告2,15页。Sherer, R. L., 1990,新墨西哥州Otero县Pajarito钇锆矿床:新墨西哥州地质,第12页,21页。Singer, D. A., 2000,碳酸盐岩矿床描述模型;美国地质调查局矿床模型:美国地质调查局,数字数据系列DDS-064,模型10,3页。参见USGS矿床模型:美国地质调查局,数字数据系列DDS-064,模型11d, 6页。Taylor, S. R, and McClennan, s.m., 1985,大陆地壳;其组成和演化:Blackwell科学出版社,牛津,312页。美国地质勘探局,2015,矿物商品摘要:美国地质调查局,196页。Vance, Z., 2013,新墨西哥州加利纳斯山脉热液ree - fluoite - ag - pb - cu矿床的矿物学,地球化学和成因[M.S.][j]:中国矿业大学学报(自然科学版),第1期。
{"title":"Gallery of Geology: Bastnaisite","authors":"V. McLemore","doi":"10.58799/nmg-v37n3.69","DOIUrl":"https://doi.org/10.58799/nmg-v37n3.69","url":null,"abstract":"New Mexico Geology 69 Verplanck, P.L., Van Gosen, B.S., Seal, R.R, and McCafferty, A.E., 2014, A deposit model for carbonatite and peralkaline intrusion-related rare earth element deposits: U.S. Geological Survey Scientific Investigations Report 2010–5070-J, 58 pp. Woolley, A. R. and Kempe, D.R.C., 1989, Carbonatites: Nomenclature, average chemical compositions and element distribution; in Bell, K., ed., Carbonatites: Genesis and Evolution: Unwin Hyman, London, pp. 1–14. Zech, R. S., Reynolds, R. L., Rosenbaum, J. G., and Brownfield, I. K., 1994, Heavy-mineral placer deposits of the Ute Mountain Ute Indian Reservation, southwestern Colorado and northwestern New Mexico: U.S. Geological Survey, Bulletin 2061-B, 39 pp. Circular 2, 15 pp. Sherer, R. L., 1990, Pajarito yttrium-zirconium deposit, Otero County, New Mexico: New Mexico Geology, v. 12, p. 21. Singer, D. A., 2000, Descriptive model of carbonatite deposits; in USGS Mineral Deposit Models: U.S. Geological Survey, Digital Data Series DDS-064, model 10, 3 pp. Staatz, M. H., 2000, Descriptive model of thorium-rare-earth veins; in USGS Mineral Deposit Models: U.S. Geological Survey, Digital Data Series DDS-064, model 11d, 6 pp. Taylor, S. R., and McClennan, S.M., 1985, The Continental Crust; its composition and evolution: Blackwell Science Publishers, Oxford, 312 pp. USGS, 2015, Mineral commodity summaries: U.S. Geological Survey, 196 pp. Vance, Z., 2013, Mineralogy, Geochemistry and Genesis of the Hydrothermal REE-Fluroite-AG-PB-CU Ore Deposits of the Gallinas Mountains, New Mexico [M.S. thesis]: Socorro, New Mexico Institute of Mining and Technology, 219 pp.","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2015-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177862","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
{"title":"In Memoriam William A. Cobban 1916-2015","authors":"S. Hook","doi":"10.58799/nmg-v37n2.55","DOIUrl":"https://doi.org/10.58799/nmg-v37n2.55","url":null,"abstract":"","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2015-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177781","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Introduction With the passing of Bill Dickinson in mid-July, the geologic community of New Mexico, and everywhere else, lost an enduring colleague and friend. By a remarkable combination of intellect, self-confidence, engaging humility, and prodigious output of published work, he influenced and challenged (to date) three generations of geoscientists and other researchers—sedimentary geologists, igneous petrologists, tectonicists, sandstone petrologists, archeologists and university students, to list a few categories—around the globe. Bill looms large on the geologic landscape of western North America and surely the Big Book on Cordilleran Tectonics contains a longish chapter entitled “The Life and Times of Bill Dickinson.” To summarize that chapter in a few pages might be considered foolish; if so, consider the following a momentary lapse of reason.
{"title":"William Richard Dickinson (1931-2015) A Personal Farewell","authors":"T. Lawton","doi":"10.58799/nmg-v37n3.70","DOIUrl":"https://doi.org/10.58799/nmg-v37n3.70","url":null,"abstract":"Introduction With the passing of Bill Dickinson in mid-July, the geologic community of New Mexico, and everywhere else, lost an enduring colleague and friend. By a remarkable combination of intellect, self-confidence, engaging humility, and prodigious output of published work, he influenced and challenged (to date) three generations of geoscientists and other researchers—sedimentary geologists, igneous petrologists, tectonicists, sandstone petrologists, archeologists and university students, to list a few categories—around the globe. Bill looms large on the geologic landscape of western North America and surely the Big Book on Cordilleran Tectonics contains a longish chapter entitled “The Life and Times of Bill Dickinson.” To summarize that chapter in a few pages might be considered foolish; if so, consider the following a momentary lapse of reason.","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2015-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177915","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
New Mexico Geology (NMG) publishes peer-reviewed geoscience papers focusing on New Mexico and the surrounding region. We aslo welcome submissions to the Gallery of Geology
{"title":"The type section of the Upper Cretaceous Tokay Tongue of the Mancos Shale (new name), Carthage coal field, Socorro County, New Mexico","authors":"S. Hook, W. A. Cobban, R. Eveleth","doi":"10.58799/nmg-v37n2.27","DOIUrl":"https://doi.org/10.58799/nmg-v37n2.27","url":null,"abstract":"New Mexico Geology (NMG) publishes peer-reviewed geoscience papers focusing on New Mexico and the surrounding region. We aslo welcome submissions to the Gallery of Geology","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2015-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177600","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
New Mexico Geology (NMG) publishes peer-reviewed geoscience papers focusing on New Mexico and the surrounding region. We aslo welcome submissions to the Gallery of Geology
{"title":"Rare Earth Elements (REE) Deposits in New Mexico: Update","authors":"T. Lawton","doi":"10.58799/nmg-v37n3.59","DOIUrl":"https://doi.org/10.58799/nmg-v37n3.59","url":null,"abstract":"New Mexico Geology (NMG) publishes peer-reviewed geoscience papers focusing on New Mexico and the surrounding region. We aslo welcome submissions to the Gallery of Geology","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2015-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177934","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
K. D. Morgan-Edel, P. Boston, M. Spilde, R. Reynolds
Phytoliths are plant-derived mineral bodies . They have been used in a variety of archaeological, environmental, and climate studies to infer paleoclimate from the vegetation types represented by diagnostic phytolith morphologies . Phytoliths can be recovered from modern plants, soils, sediments, lacustrine deposits, eolian deposits, archaeological sites, plant fossils, and potentially allochthonous sediment deposits in caves . In order to interpret such data, documentation of modern plant-derived minerals is needed, especially in arid regimes . Four goals were attempted in this study, 1) provide a morphological description of the different types of biomineralization products from the modern plant species of creosote and horsetail, two Southwestern plants with significantly different environmental requirements; 2) describe the elemental chemistry and mineralogy of the phytoliths from these plants; 3) describe morphological changes to biominerals during experimental mechanical weathering and abrasion processes, and; 4) compare all of these results to identified fragments of potential phytoliths and preserved plant-derived minerals from Fort Stanton Cave sediments and Miocene-aged plant fossils from the Rainbow Loop Flora of the Barstow Formation . This study examines biominerals from two modern key indicator species in the arid Southwest U . S . A . : Larrea tridentata (DC . ) Coville (creosote), which is characteristic of North American hot arid regimes, and Equisetum hyemale L . (horsetail), a known silica accumulating plant from wet environments and an indicator of riparian areas within desert environments . Creosote and horsetail produce biominerals that are different from one another, and possibly unique to the species or genus level of identification . We conducted a series of observations, analyses, and experiments including: 1) analysis of plant tissues with scanning electron microscopy (SEM) with energy dispersive x-ray (EDX) and x-ray diffraction (XRD); 2) investigation of preservation potential by documenting morphological changes to phytoliths after simulated mechanical weathering for different lengths of time; and 3) modern and weathered biominerals from creosote and horsetail were compared to sediments and fossils of different ages from two study sites, Fort Stanton Cave, Lincoln County, New Mexico and the Barstow Formation, San Bernardino County, California . Both study sites revealed preserved phytoliths indicating potential long-term preservation and the potential for application of these structures as vegetation paleoclimate indicators . All phytolith types from modern plant material were still distinguishable after simulated weathering treatments .
植物岩是植物衍生的矿体。它们已被用于各种考古、环境和气候研究,从诊断植物岩形态所代表的植被类型推断古气候。植物岩可以从现代植物、土壤、沉积物、湖泊沉积物、风成沉积物、考古遗址、植物化石和洞穴中潜在的外来沉积物中回收。为了解释这些数据,需要记录现代植物衍生矿物,特别是在干旱地区。本研究旨在实现以下四个目标:1)对环境要求差异显著的现代植物木酚油和马尾草中不同类型的生物矿化产物进行形态学描述;2)描述这些植物的植物岩的元素化学和矿物学特征;3)描述生物矿物在实验机械风化磨损过程中的形态变化;4)将所有这些结果与斯坦顿堡洞穴沉积物中鉴定的潜在植物岩碎片和保存的植物源矿物以及巴斯托组彩虹环区中新世植物化石进行比较。本文研究了美国西南部干旱地区两个现代关键指示种的生物矿物。年代。一个。:三叉戟(DC .)北美洲炎热干旱地区特有的木馏油(Coville)和Equisetum hyemale L .;(马尾),一种已知的从潮湿环境中积累二氧化硅的植物,是沙漠环境中河岸地区的指示物。杂酚油和马尾油产生的生物矿物彼此不同,并且可能在物种或属的鉴定水平上是独一无二的。我们进行了一系列的观察、分析和实验,包括:1)利用扫描电子显微镜(SEM)、能量色散x射线(EDX)和x射线衍射(XRD)对植物组织进行分析;2)通过记录植物岩在不同时间模拟机械风化后的形态变化,探讨植物岩的保存潜力;3)将来自木馏油和马尾油的现代和风化生物矿物与来自新墨西哥州林肯县斯坦顿堡洞穴和加利福尼亚州圣贝纳迪诺县巴斯托组两个研究地点的不同时代的沉积物和化石进行比较。两个研究地点都发现了保存完好的植物岩,这表明这些植物岩具有长期保存的潜力,并有可能作为植被古气候指标。经过模拟风化处理后,现代植物材料中的所有植物岩类型仍可区分。
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Late Pennsylvanian sedimentation in New Mexico was in part affected by global glacio-eustasy, as the ice sheets of Late Paleozoic Gonwana waxed and waned. A primary effect of the glacial cycles may be seen in shallowing upward marine successions in the Pangean tropics, which is exactly where New Mexico was located during the Late Pennsylvanian. The top of one such cycle is very well exposed in Mine Canyon in the Caballo Mountains of Sierra County (section 32, T16S, R3W). Here, strata of the middle part (Virgilian) of the Bar B Formation include a bed first described by Soreghan (1992) in her unpublished dissertation as a cryptokarst (this is her Caballo Mountains section; also see Soreghan, 1994) The succession begins with about 4.5 m of cherty limestone that is a crinoid-brachiopod wackestone with some shale interbeds. The overlying 1.5 m of limestone is also a crinoid-brachiopod wackestone but lacks chert and the shale interbeds. A sharp and wavy contact surface at the top of the chert-free limestone separates it from 0.6 m of overlying nodular limestone. Above that is 2.9 m of marly yellow shale. On face value, in the field, this looks like a shallow marine facies (the lower limestones) that was subarerially exposed so that the nodular limestone weathered in a subaerial setting to form a paleosol with calcrete. This is thus a dramatic shallowing upward, often explained as the effect of a glacial drawdown of sea level. However, we should note that this bed succession is only found locally (in Mine Canyon), not in other outcrops of the Bar B Formation (Lucas et al. 2012), so whether or not it represents a widespread, glacio-eustatic event can be questioned. It more likely reflects a very local tectonic or autocyclic depositional event. If we look at the nodular limestone bed in thin section, it is a mudstone displaying an inhomogeneous texture of nodular fabric, partly clotted fabric with dark gray micritic grains (peloidal grains, glaebules; mostly 0.1–0.5 mm in diameter, some larger grains are present) floating in a light gray micritc matrix. Some of the micritic grains are coated by darker micritic rims. Locally, sparite-filled circumgranular shrinkage cracks are well developed. The mudstone is locally fractured by abundant wrinkled microcracks. A few irregular pores are present that are filled with sparite and separated by interconnecting micritic bridges. We interpret these irregular pores as root structures. All these features indicate that this limestone bed is a paleosol of calcrete nodules. Soreghan (1992, 1994) noted the presence of numerous exposure surfaces in Upper Pennsylvanian strata in southern New Mexico. These exposure surfaces are marked by laminar calcrete crusts, and features resembling terra rossa, paleosol, and regolith development. Soreghan (1992) identified cryptokarst surfaces but did not define the term cryptokarst, and also did not describe these cryptokarst surfaces in detail. Field (2002) defined cryptokarst as, “a
{"title":"Gallery of Geology - Pennsylvanian paleosol in Sierra County, New Mexico","authors":"S. Lucas","doi":"10.58799/nmg-v36n1.25","DOIUrl":"https://doi.org/10.58799/nmg-v36n1.25","url":null,"abstract":"Late Pennsylvanian sedimentation in New Mexico was in part affected by global glacio-eustasy, as the ice sheets of Late Paleozoic Gonwana waxed and waned. A primary effect of the glacial cycles may be seen in shallowing upward marine successions in the Pangean tropics, which is exactly where New Mexico was located during the Late Pennsylvanian. The top of one such cycle is very well exposed in Mine Canyon in the Caballo Mountains of Sierra County (section 32, T16S, R3W). Here, strata of the middle part (Virgilian) of the Bar B Formation include a bed first described by Soreghan (1992) in her unpublished dissertation as a cryptokarst (this is her Caballo Mountains section; also see Soreghan, 1994) The succession begins with about 4.5 m of cherty limestone that is a crinoid-brachiopod wackestone with some shale interbeds. The overlying 1.5 m of limestone is also a crinoid-brachiopod wackestone but lacks chert and the shale interbeds. A sharp and wavy contact surface at the top of the chert-free limestone separates it from 0.6 m of overlying nodular limestone. Above that is 2.9 m of marly yellow shale. On face value, in the field, this looks like a shallow marine facies (the lower limestones) that was subarerially exposed so that the nodular limestone weathered in a subaerial setting to form a paleosol with calcrete. This is thus a dramatic shallowing upward, often explained as the effect of a glacial drawdown of sea level. However, we should note that this bed succession is only found locally (in Mine Canyon), not in other outcrops of the Bar B Formation (Lucas et al. 2012), so whether or not it represents a widespread, glacio-eustatic event can be questioned. It more likely reflects a very local tectonic or autocyclic depositional event. If we look at the nodular limestone bed in thin section, it is a mudstone displaying an inhomogeneous texture of nodular fabric, partly clotted fabric with dark gray micritic grains (peloidal grains, glaebules; mostly 0.1–0.5 mm in diameter, some larger grains are present) floating in a light gray micritc matrix. Some of the micritic grains are coated by darker micritic rims. Locally, sparite-filled circumgranular shrinkage cracks are well developed. The mudstone is locally fractured by abundant wrinkled microcracks. A few irregular pores are present that are filled with sparite and separated by interconnecting micritic bridges. We interpret these irregular pores as root structures. All these features indicate that this limestone bed is a paleosol of calcrete nodules. Soreghan (1992, 1994) noted the presence of numerous exposure surfaces in Upper Pennsylvanian strata in southern New Mexico. These exposure surfaces are marked by laminar calcrete crusts, and features resembling terra rossa, paleosol, and regolith development. Soreghan (1992) identified cryptokarst surfaces but did not define the term cryptokarst, and also did not describe these cryptokarst surfaces in detail. Field (2002) defined cryptokarst as, “a ","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2014-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71175914","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
S. Lucas, G. Morgan, D. Love, Craig R. Bejnar, B. Sion, N. Dunbar, R. Chamberlin
New Mexico Geology (NMG) publishes peer-reviewed geoscience papers focusing on New Mexico and the surrounding region. We aslo welcome submissions to the Gallery of Geology
{"title":"Description, classification, and geologic context of a Lower Pleistocene primitive mammoth jaw from Matanza Arroyo near Socorro, New Mexico","authors":"S. Lucas, G. Morgan, D. Love, Craig R. Bejnar, B. Sion, N. Dunbar, R. Chamberlin","doi":"10.58799/nmg-v36n3.47","DOIUrl":"https://doi.org/10.58799/nmg-v36n3.47","url":null,"abstract":"New Mexico Geology (NMG) publishes peer-reviewed geoscience papers focusing on New Mexico and the surrounding region. We aslo welcome submissions to the Gallery of Geology","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2014-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71176056","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
At Cedro Peak in the Manzanita Mountains of Bernalillo County, New Mexico, a nearly complete, structurally uncomplicated, fossiliferous and characteristic local Pennsylvanian section is exposed. Approximately 340 m thick, we assign this section to the (in ascending order) Sandia, Gray Mesa (= Los Moyos), Atrasado (= Wild Cow), and Bursum Formations. We divide the Gray Mesa Formation into the (in ascending order) Elephant Butte, Whiskey Canyon, and Garcia Members, and we divide the Atrasado Formation into the (in ascending order) Bartolo, Amado, Tinajas, Council Spring, Burrego, Story, Del Cuerto, and Moya Members. We thus reject the names Sol se Mete, Pine Shadow, and La Casa for member-level subdivisions of the Atrasado Formation. We describe the lithostratigraphy, microfacies, and paleontology of the Pennsylvanian strata at Cedro Peak to interpret their depositional environments and age. The approximately 14-m-thick Sandia Formation is almost entirely of nonmarine origin and is assigned an Atokan age based on regional correlations. The approximately 119-m-thick Gray Mesa Formation records normal marine deposition. It contains fusulinids from latest Atokan? to middle Desmoinesian age. The approximately 200-m-thick Atrasado Formation is a complex succession of marine and nonmarine (mostly fluvial-deltaic) strata. It contains fusulinids of Missourian and middle Virgilian age. Only the lowermost 6 m of the Bursum Formation are exposed at Cedro Peak, but nearby sections indicate a Bursum thickness of approximately 90 m and yield Virgilian-age fusulinids. The continuity of the stratigraphic architecture of the Gray Mesa and Atrasado Formations from the Oscura Mountains in Socorro County to Cedro Peak, a distance of approximately 150 km, suggests that Middle–Late Pennsylvanian sedimentation was driven by the same underlying forces over much of central New Mexico. We posit these forces as a series of tectonic events overprinted at a few points by eustatic cycles.
在新墨西哥州伯纳利略县曼萨尼塔山脉的塞德罗峰,一个几乎完整,结构简单,化石和典型的当地宾夕法尼亚剖面被暴露出来。大约340米厚,我们将该剖面划分为(按升序排列)Sandia、Gray Mesa (= Los Moyos)、Atrasado (= Wild Cow)和Bursum地层。我们将格雷梅萨地层分为(按升序排列)象丘、威士忌峡谷和加西亚成员,我们将阿特拉萨多地层分为(按升序排列)巴托洛、阿马多、蒂纳哈斯、Council Spring、Burrego、Story、Del Cuerto和莫亚成员。因此,我们拒绝将Sol se Mete、Pine Shadow和La Casa命名为Atrasado组的成员级细分。我们描述了塞德罗峰宾夕法尼亚系地层的岩石地层、微相和古生物学,以解释它们的沉积环境和时代。大约14米厚的Sandia组几乎完全是非海相形成的,并根据区域相关性确定为Atokan时代。约119米厚的灰色台地组记录了正常的海相沉积。它含有最新的Atokan?到德摩尼时代中期。约200米厚的Atrasado组是一个复杂的海相和非海相(主要是河流三角洲)地层演替。它含有密苏里州和弗吉尼亚中年时期的镰刀碱。在塞德罗峰只露出了Bursum组最下面的6米,但附近的剖面显示Bursum组的厚度约为90米,并产生了弗吉尼亚时代的fusulinids。从索科罗县的奥斯库拉山脉到塞德罗峰,距离大约150公里,格雷梅萨和阿特拉萨多地层结构的连续性表明,宾夕法尼亚中晚期的沉积是由新墨西哥州中部大部分地区相同的潜在力量驱动的。我们假设这些力是一系列的构造事件,在几个点上叠加了上升周期。
{"title":"The Pennsylvanian section at Cedro Peak: A local Pennsylvanian reference section in the Manzanita Mountains, central New Mexico (USA)","authors":"S. Lucas, K. Krainer, B. Allen, D. Vachard","doi":"10.58799/nmg-v36n1.3","DOIUrl":"https://doi.org/10.58799/nmg-v36n1.3","url":null,"abstract":"At Cedro Peak in the Manzanita Mountains of Bernalillo County, New Mexico, a nearly complete, structurally uncomplicated, fossiliferous and characteristic local Pennsylvanian section is exposed. Approximately 340 m thick, we assign this section to the (in ascending order) Sandia, Gray Mesa (= Los Moyos), Atrasado (= Wild Cow), and Bursum Formations. We divide the Gray Mesa Formation into the (in ascending order) Elephant Butte, Whiskey Canyon, and Garcia Members, and we divide the Atrasado Formation into the (in ascending order) Bartolo, Amado, Tinajas, Council Spring, Burrego, Story, Del Cuerto, and Moya Members. We thus reject the names Sol se Mete, Pine Shadow, and La Casa for member-level subdivisions of the Atrasado Formation. We describe the lithostratigraphy, microfacies, and paleontology of the Pennsylvanian strata at Cedro Peak to interpret their depositional environments and age. The approximately 14-m-thick Sandia Formation is almost entirely of nonmarine origin and is assigned an Atokan age based on regional correlations. The approximately 119-m-thick Gray Mesa Formation records normal marine deposition. It contains fusulinids from latest Atokan? to middle Desmoinesian age. The approximately 200-m-thick Atrasado Formation is a complex succession of marine and nonmarine (mostly fluvial-deltaic) strata. It contains fusulinids of Missourian and middle Virgilian age. Only the lowermost 6 m of the Bursum Formation are exposed at Cedro Peak, but nearby sections indicate a Bursum thickness of approximately 90 m and yield Virgilian-age fusulinids. The continuity of the stratigraphic architecture of the Gray Mesa and Atrasado Formations from the Oscura Mountains in Socorro County to Cedro Peak, a distance of approximately 150 km, suggests that Middle–Late Pennsylvanian sedimentation was driven by the same underlying forces over much of central New Mexico. We posit these forces as a series of tectonic events overprinted at a few points by eustatic cycles.","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2014-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71176270","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Since reconnaissance work in the early 20 th century, the existence of Pleistocene glaciers on Mount Taylor has been recognized in compilations of Rocky Mountain glaciation. This eroded composite volcano stands alone as the most prominent topographic element of the Colorado Plateau in west-central New Mexico. Its highest elevations, however, rise only a few hundred meters above the lowest late Pleistocene equilibrium line altitudes (paleo-ELAs) in the region, and potential cirques on the mountain are at best weakly developed. The valley head most likely to be a cirque lies just northeast of La Mosca Peak. We found possible terminal moraines in this valley floor; alternative interpretations of these bouldery features as rock glacier toes or landslide deposits appear less probable, but cannot be ruled out. A search for striated clasts or bedrock in this area was unsuccessful, but fractured andesitic rocks such as those on Mount Taylor do not typically preserve such features. Using the possible moraines to reconstruct a small cirque glacier yields an equilibrium line altitude of approximately 3,220 m by the accumulation area ratio method, within the regional range of paleo-ELAs. Pleistocene glaciation on Mount Taylor remains uncertain, but is unlikely to have occurred for any significant period in the eastern amphitheater of the mountain where it was previously inferred.
{"title":"Was Mount Taylor glaciated in the Late Pleistocene? An analysis based on field evidence and regional equilibrium line altitudes","authors":"G. Meyer, P. Watt, M. Wilder","doi":"10.58799/nmg-v36n2.32","DOIUrl":"https://doi.org/10.58799/nmg-v36n2.32","url":null,"abstract":"Since reconnaissance work in the early 20 th century, the existence of Pleistocene glaciers on Mount Taylor has been recognized in compilations of Rocky Mountain glaciation. This eroded composite volcano stands alone as the most prominent topographic element of the Colorado Plateau in west-central New Mexico. Its highest elevations, however, rise only a few hundred meters above the lowest late Pleistocene equilibrium line altitudes (paleo-ELAs) in the region, and potential cirques on the mountain are at best weakly developed. The valley head most likely to be a cirque lies just northeast of La Mosca Peak. We found possible terminal moraines in this valley floor; alternative interpretations of these bouldery features as rock glacier toes or landslide deposits appear less probable, but cannot be ruled out. A search for striated clasts or bedrock in this area was unsuccessful, but fractured andesitic rocks such as those on Mount Taylor do not typically preserve such features. Using the possible moraines to reconstruct a small cirque glacier yields an equilibrium line altitude of approximately 3,220 m by the accumulation area ratio method, within the regional range of paleo-ELAs. Pleistocene glaciation on Mount Taylor remains uncertain, but is unlikely to have occurred for any significant period in the eastern amphitheater of the mountain where it was previously inferred.","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2014-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71176340","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
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