The Cebolleta uranium project in northwestern New Mexico is the site of five sandstone-hosted uranium deposits contained within the Jackpile Sandstone Member of the Upper Jurassic Morrison Formation. The uranium mineralization, which has been well-delineated by numerous drill holes, two open-pit and three underground mines, is a series of tabular shaped bodies that were deposited within individual sandstone lenses of the Jackpile Sandstone. Uranium deposits in the project area exhibit characteristics of “trend,” “redistributed,” and “remnant” types of deposits, as described elsewhere within the Grants mineral belt. Significant uranium resources are present in the project area. Introduction The Cebolleta uranium project of Uranium Resources, Incorporated (URI), is located in the Laguna mining district of northeastern Cibola County, New Mexico (Fig. 1). Situated in northwestern New Mexico east of Mount Taylor, the project is approximately 72 km west of the city of Albuquerque and 16 km north-northeast of the Pueblo of Laguna. The Cebolleta project lies in an area of valleys and mesas along the southeastern margin of the San Juan Basin. Elevations within the project area range from approximately 1,798 to 1,983 m above sea level. The project area (Fig. 2), which hosts five significant sandstone-hosted uranium deposits, is positioned near the eastern end of the so-called Grants mineral belt, which Church Rock-Crownpoint subdistrict Smith Lake subditrict Ambrosia Lake subdistrict Nose Rock subdistrict
{"title":"Uranium deposits at the Cebolleta project, Laguna mining district, Cibola County, New Mexico","authors":"Ted Wilton","doi":"10.58799/nmg-v39n1.1","DOIUrl":"https://doi.org/10.58799/nmg-v39n1.1","url":null,"abstract":"The Cebolleta uranium project in northwestern New Mexico is the site of five sandstone-hosted uranium deposits contained within the Jackpile Sandstone Member of the Upper Jurassic Morrison Formation. The uranium mineralization, which has been well-delineated by numerous drill holes, two open-pit and three underground mines, is a series of tabular shaped bodies that were deposited within individual sandstone lenses of the Jackpile Sandstone. Uranium deposits in the project area exhibit characteristics of “trend,” “redistributed,” and “remnant” types of deposits, as described elsewhere within the Grants mineral belt. Significant uranium resources are present in the project area. Introduction The Cebolleta uranium project of Uranium Resources, Incorporated (URI), is located in the Laguna mining district of northeastern Cibola County, New Mexico (Fig. 1). Situated in northwestern New Mexico east of Mount Taylor, the project is approximately 72 km west of the city of Albuquerque and 16 km north-northeast of the Pueblo of Laguna. The Cebolleta project lies in an area of valleys and mesas along the southeastern margin of the San Juan Basin. Elevations within the project area range from approximately 1,798 to 1,983 m above sea level. The project area (Fig. 2), which hosts five significant sandstone-hosted uranium deposits, is positioned near the eastern end of the so-called Grants mineral belt, which Church Rock-Crownpoint subdistrict Smith Lake subditrict Ambrosia Lake subdistrict Nose Rock subdistrict","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2017-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71178206","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":"The rare and unusual pseudofossil Astropolithon from the Lower Permian Abo Formation near Socorro, New Mexico","authors":"S. Lucas, A. J. Lerner","doi":"10.58799/nmg-v39n2.40","DOIUrl":"https://doi.org/10.58799/nmg-v39n2.40","url":null,"abstract":"","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2017-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71178343","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":"Gallery of Geology: Uranium Mining in the Grants Area","authors":"V. McLemore, B. Frey","doi":"10.58799/nmg-v39n1.25","DOIUrl":"https://doi.org/10.58799/nmg-v39n1.25","url":null,"abstract":"","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2017-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71178277","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}
Tellurium (Te) is one of the least abundant elements in the crust and tends to form minerals associated with gold, silver, bismuth, copper, lead, and zinc sulfide deposits. There are no primary tellurium mines in the world; most tellurium production comes from the anode slimes generated in metal refining, primarily from copper porphyry deposits. Tellurium is used as an alloying agent in iron and steel, as catalysts, and in the chemical industry. However, future demand and production could increase because tellurium is progressively used in thin film cadmium-tellurium solar panels and some electronic devices. In New Mexico, anomalous amounts of tellurium are found associated with porphyry copper deposits, as well as with gold-silver vein deposits, but were not considered important exploration targets in the past. The only tellurium production from New Mexico has been from the Lone Pine deposit (Wilcox district) in the Mogollon Mountains, where approximately 5 tons of tellurium ore were produced. Gold-tellurides are found with gold, silver, pyrite, and fluorite in fracture-filling veins in rhyolite at Lone Pine, with reported assays as much as 5,000 ppm Te. Tellurium-bearing deposits also are found in the Organ Mountains, Sylvanite, Tierra Blanca, Grandview Canyon, and Hillsboro districts. Additional detailed sampling and geologic mapping are required of the New Mexico deposits to fully understand the mineralogy and economic potential of tellurium.
{"title":"Tellurium resources in New Mexico","authors":"V. McLemore","doi":"10.58799/nmg-v38n1.1","DOIUrl":"https://doi.org/10.58799/nmg-v38n1.1","url":null,"abstract":"Tellurium (Te) is one of the least abundant elements in the crust and tends to form minerals associated with gold, silver, bismuth, copper, lead, and zinc sulfide deposits. There are no primary tellurium mines in the world; most tellurium production comes from the anode slimes generated in metal refining, primarily from copper porphyry deposits. Tellurium is used as an alloying agent in iron and steel, as catalysts, and in the chemical industry. However, future demand and production could increase because tellurium is progressively used in thin film cadmium-tellurium solar panels and some electronic devices. In New Mexico, anomalous amounts of tellurium are found associated with porphyry copper deposits, as well as with gold-silver vein deposits, but were not considered important exploration targets in the past. The only tellurium production from New Mexico has been from the Lone Pine deposit (Wilcox district) in the Mogollon Mountains, where approximately 5 tons of tellurium ore were produced. Gold-tellurides are found with gold, silver, pyrite, and fluorite in fracture-filling veins in rhyolite at Lone Pine, with reported assays as much as 5,000 ppm Te. Tellurium-bearing deposits also are found in the Organ Mountains, Sylvanite, Tierra Blanca, Grandview Canyon, and Hillsboro districts. Additional detailed sampling and geologic mapping are required of the New Mexico deposits to fully understand the mineralogy and economic potential of tellurium.","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2016-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177526","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}
G. Woldegabriel, R. Kelley, E. D. Miller, E. Schultz-Fellenz
New Mexico Geology May 2016, Volume 38, Number 2 Sporadic mafic and felsic eruptions, representing at least five major and several smaller pulses of effusive and explosive volcanic products that range in age from 25.5 Ma to 68.3 ka, crop out within the Jemez volcanic field and the surrounding areas in north-central New Mexico (Kelley et al., 2014 and references therein). The youngest pyroclastic and lava flows erupted from the southern moat of the Valles caldera. These volcanic products belong to the El Cajete Pyroclastic Beds and co-erupted Battleship Rock Ignimbrite, which are locally overlain by the Banco Bonito obsidian flow (Gardner et al, 2010). Based on detailed field mapping, Wolff et al. (2011) suggested that more than 10 km3 of silicic magma was erupted to form the fallout and ash-flow deposits of the lower and upper units of the El Cajete Pyroclastic Beds and the Battleship Rock Ignimbrite, whereas the volume of the Banco Bonito obsidian lava flow was estimated at 4 km3. The mostly Plinian eruptions of the El Cajete Pyroclastic Beds were distributed over much of the Valles caldera, the southern Jemez Mountains, and the Rio Grande rift, including considerable ash deposited in the Santa Fe area and in eastern New Mexico (Wolff et al., 2011). As shown in Figure 1, recent field studies identified >4 m thick of proximal and ≥1 m thick of distal primary pumice deposit near the vent (A) and in the Cerros Gallery of Geology
新墨西哥州地质,2016年5月,第38卷,第2号零星的基性和长英质火山喷发,代表了至少五个主要的和几个较小的喷发和火山产品脉冲,年龄范围从25.5 Ma到68.3 ka,在新墨西哥州中北部的Jemez火山田和周围地区出现(Kelley等,2014和其中的参考文献)。最年轻的火山碎屑和熔岩流从山谷火山口的南部护城河喷发出来。这些火山产物属于El Cajete火山碎屑床和共喷发的战舰岩火成岩,其局部被Banco Bonito黑曜岩流覆盖(Gardner et al, 2010)。Wolff et al.(2011)根据详细的野外作图,认为喷发了超过10 km3的硅岩浆,形成了El Cajete火山碎屑床和Battleship Rock Ignimbrite的上下单元的沉降物和灰流沉积物,而Banco Bonito黑曜岩熔岩流的体积估计为4 km3。El Cajete火山碎屑床的普林尼期喷发主要分布在Valles火山口、Jemez山脉南部和里约热内卢Grande裂谷的大部分地区,包括圣达菲地区和新墨西哥州东部的大量火山灰沉积(Wolff et al., 2011)。如图1所示,最近的现场研究发现,在火山口(A)附近和Cerros地质画廊,近端原生浮石矿床厚度为bb40 m,远端原生浮石矿床厚度≥1 m
{"title":"The youngest silicic eruptions from the Valles Caldera and volcanic hazard potential in north-central New Mexico","authors":"G. Woldegabriel, R. Kelley, E. D. Miller, E. Schultz-Fellenz","doi":"10.58799/nmg-v38n2.50","DOIUrl":"https://doi.org/10.58799/nmg-v38n2.50","url":null,"abstract":"New Mexico Geology May 2016, Volume 38, Number 2 Sporadic mafic and felsic eruptions, representing at least five major and several smaller pulses of effusive and explosive volcanic products that range in age from 25.5 Ma to 68.3 ka, crop out within the Jemez volcanic field and the surrounding areas in north-central New Mexico (Kelley et al., 2014 and references therein). The youngest pyroclastic and lava flows erupted from the southern moat of the Valles caldera. These volcanic products belong to the El Cajete Pyroclastic Beds and co-erupted Battleship Rock Ignimbrite, which are locally overlain by the Banco Bonito obsidian flow (Gardner et al, 2010). Based on detailed field mapping, Wolff et al. (2011) suggested that more than 10 km3 of silicic magma was erupted to form the fallout and ash-flow deposits of the lower and upper units of the El Cajete Pyroclastic Beds and the Battleship Rock Ignimbrite, whereas the volume of the Banco Bonito obsidian lava flow was estimated at 4 km3. The mostly Plinian eruptions of the El Cajete Pyroclastic Beds were distributed over much of the Valles caldera, the southern Jemez Mountains, and the Rio Grande rift, including considerable ash deposited in the Santa Fe area and in eastern New Mexico (Wolff et al., 2011). As shown in Figure 1, recent field studies identified >4 m thick of proximal and ≥1 m thick of distal primary pumice deposit near the vent (A) and in the Cerros Gallery of Geology","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2016-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177761","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":"Tellurium minerals in New Mexico","authors":"V.W. Lueth","doi":"10.58799/nmg-v38n1.17","DOIUrl":"https://doi.org/10.58799/nmg-v38n1.17","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":"2016-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177615","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}
We use stratigraphic relations, paleoflow data, and 40Ar/39Ar dating to interpret net aggradation, punctuated by at least two minor incisional events, along part of the upper ancestral Rio Grande fluvial system between 5.5 and 4.5 Ma (in northern New Mexico). The studied fluvial deposits, which we informally call the Sandlin unit of the Santa Fe Group, overlie a structural high between the San Luis and Española Basins. The Sandlin unit was deposited by two merging, westto southwest-flowing, ancestral Rio Grande tributaries respectively sourced in the central Taos Mountains and southern Taos Mountains-northeastern Picuris Mountains. The river confluence progressively shifted southwestward (downstream) with time, and the integrated river (ancestral Rio Grande) flowed southwards into the Española Basin to merge with the ancestral Rio Chama. Just prior to the end of the Miocene, this fluvial system was incised in the southern part of the study area (resulting in an approximately 4–7 km wide paleovalley), and had sufficient competency to transport cobbles and boulders. Sometime between emplacement of two basalt flows dated at 5.54± 0.38 Ma and 4.82±0.20 Ma (groundmass 40Ar/39Ar ages), this fluvial system deposited 10–12 m of sandier sediment (lower Sandlin subunit) preserved in the northern part of this paleovalley. The fluvial system widened between 4.82±0.20 and 4.50±0.07 Ma, depositing coarse sand and fine gravel up to 14 km north of the present-day Rio Grande. This 10–25 m-thick sediment package (upper Sandlin unit) buried earlier southto southeast-trending paleovalleys (500–800 m wide) inferred from aeromagnetic data. Two brief incisional events are recognized. The first was caused by the 4.82±0.20 Ma basalt flow impounding south-flowing paleodrainages, and the second occurred shortly after emplacement of a 4.69±0.09 Ma basalt flow in the northern study area. Drivers responsible for Sandlin unit aggradation may include climate-modulated hydrologic factors (i.e., variable sediment supply and water discharge) or a reduction of eastward tilt rates of the southern San Luis Basin half graben. If regional in extent, these phenomena could also have promoted fluvial spillover that occurred in the southern Albuquerque Basin at about 6–5 Ma, resulting in southward expansion of the Rio Grande to southern New Mexico.
{"title":"Latest Miocene-earliest Pliocene evolution of the ancestral Rio Grande at the Espa�ola-San Luis Basin boundary, northern New Mexico","authors":"D. Koning, S. Aby, V. Grauch, M. Zimmerer","doi":"10.58799/nmg-v38n2.24","DOIUrl":"https://doi.org/10.58799/nmg-v38n2.24","url":null,"abstract":"We use stratigraphic relations, paleoflow data, and 40Ar/39Ar dating to interpret net aggradation, punctuated by at least two minor incisional events, along part of the upper ancestral Rio Grande fluvial system between 5.5 and 4.5 Ma (in northern New Mexico). The studied fluvial deposits, which we informally call the Sandlin unit of the Santa Fe Group, overlie a structural high between the San Luis and Española Basins. The Sandlin unit was deposited by two merging, westto southwest-flowing, ancestral Rio Grande tributaries respectively sourced in the central Taos Mountains and southern Taos Mountains-northeastern Picuris Mountains. The river confluence progressively shifted southwestward (downstream) with time, and the integrated river (ancestral Rio Grande) flowed southwards into the Española Basin to merge with the ancestral Rio Chama. Just prior to the end of the Miocene, this fluvial system was incised in the southern part of the study area (resulting in an approximately 4–7 km wide paleovalley), and had sufficient competency to transport cobbles and boulders. Sometime between emplacement of two basalt flows dated at 5.54± 0.38 Ma and 4.82±0.20 Ma (groundmass 40Ar/39Ar ages), this fluvial system deposited 10–12 m of sandier sediment (lower Sandlin subunit) preserved in the northern part of this paleovalley. The fluvial system widened between 4.82±0.20 and 4.50±0.07 Ma, depositing coarse sand and fine gravel up to 14 km north of the present-day Rio Grande. This 10–25 m-thick sediment package (upper Sandlin unit) buried earlier southto southeast-trending paleovalleys (500–800 m wide) inferred from aeromagnetic data. Two brief incisional events are recognized. The first was caused by the 4.82±0.20 Ma basalt flow impounding south-flowing paleodrainages, and the second occurred shortly after emplacement of a 4.69±0.09 Ma basalt flow in the northern study area. Drivers responsible for Sandlin unit aggradation may include climate-modulated hydrologic factors (i.e., variable sediment supply and water discharge) or a reduction of eastward tilt rates of the southern San Luis Basin half graben. If regional in extent, these phenomena could also have promoted fluvial spillover that occurred in the southern Albuquerque Basin at about 6–5 Ma, resulting in southward expansion of the Rio Grande to southern New Mexico.","PeriodicalId":35824,"journal":{"name":"New Mexico Geology","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2016-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"71177706","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}
During the late Paleozoic (Pennsylvanian–Early Permian), the collision of Gondwana and Laurussia (Euramerica) created the Pangean supercontinent . That collision caused extensive tectonism along a then nearly equatorial zone that extended from eastern Europe to western North America . In the United States, from Illinois to Idaho, the Ancestral Rocky Mountains (ARM) formed as a lengthy belt of basement-cored uplifts (e .g ., Kluth and Coney 1981; McBride and Nelson 1998; Dickinson and Lawton 2003) . In New Mexico, these uplifts were mostly north-south oriented islands surrounded by shallow seas during the Pennsylvanian that were ultimately worn down and buried by alluvial sediments during the Early Permian (Woodward et al . 1999) . Deciphering many aspects of ARM tectonism in New Mexico has been difficult because few late Paleozoic structures are preserved intact (e .g ., Woodward et al ., 1999) . Indeed, most of these structures were reactivated by tectonism during the Late Cretaceous–Eocene Laramide orogeny or during the late Cenozoic tectonism associated with Basin and Range extension, notably of the Rio Grande rift . Perhaps the best documented ARM structures are those described by Bachman and Hayes (1958), Pray (1961) and others in the Sacramento Mountains of Otero County, where folded Pennsylvanian strata are truncated by nearly flat lying Permian red beds . Here, we document a small ARM structure in the southern Robledo Mountains of Doña Ana County . This structure is within the confines of the Prehistoric Trackways National Monument (PTNM) . The PTNM is approximately 2,137 hectares (5,280 acres) of land protected by an act of the U . S Congress primarily because of its world-class Early Permian trace-fossil assemblages (Lucas et al . 2011) . The trace fossils come from a lithostratigraphic unit referred to as the Robledo Mountains Formation of the Hueco Group (termed Abo Tongue or Abo Member of the Hueco Formation in older stratigraphic terminology, Seager et al ., 2008) . In the PTNM, the Robledo Mountains Formation is composed of approximately two-thirds drab-colored marine limestone and shale interbedded with one-third red terrestrial mudstone, siltstone and sandstone . The formation has an average thickness of 120 m . The siliciclastic red beds yield the trace fossils for which the PTNM was created . Voigt et al . (2013) recently argued that these sediments formed on a coastal floodplain during alternating wet and dry conditions . They based this conclusion on detailed sedimentological and ichnological analysis that indicates most of the trace fossils found in the Robledo Mountains Formation red beds were preserved on mud-draped surfaces within distal crevasse-splay siltstone to fine-grained sandstone . The physical and biological structures recorded in their study support the reconstruction of a freshwater ecosystem dominated
在晚古生代(宾夕法尼亚-早二叠纪),冈瓦纳和劳鲁西亚(北美洲)的碰撞形成了泛古大陆。那次碰撞引起了当时从东欧延伸到北美西部的近赤道地区的广泛构造运动。在美国,从伊利诺斯州到爱达荷州,祖先落基山脉(ARM)形成了一条长长的以地下室为核心的隆起带(例如,Kluth和Coney 1981;McBride and Nelson 1998;Dickinson and Lawton 2003)。在新墨西哥州,这些隆起在宾夕法尼亚时期主要是南北走向的岛屿,周围是浅海,最终在早二叠纪时期被冲积沉积物磨损和掩埋(Woodward等)。1999)。破译新墨西哥州ARM构造的许多方面一直很困难,因为很少有晚古生代的构造完好无损(例如,Woodward et al ., 1999)。事实上,这些构造大部分是在晚白垩世-始新世拉腊米造山运动或晚新生代盆地和山脉伸展相关的构造作用下重新激活的,特别是里约热内卢大裂谷。也许记录最好的ARM构造是由Bachman和Hayes (1958), Pray(1961)和其他人在Otero县萨克拉门托山脉描述的,在那里褶皱的宾夕法尼亚地层被几乎平坦的二叠纪红层截断。在这里,我们在Doña Ana县的Robledo山脉南部记录了一个小的ARM结构。这个结构是在史前轨道国家纪念碑(PTNM)的范围内。PTNM约有2137公顷(5280英亩)的土地,受美国法律保护。主要是因为其世界级的早二叠纪化石组合(Lucas et al .)。2011)。痕迹化石来自Hueco组的Robledo山组(在较旧的地层术语中称为Abo舌或Hueco组Abo成员,Seager et al ., 2008)的岩石地层单元。在PTNM, Robledo山脉组由大约三分之二的灰褐色海相灰岩和页岩组成,三分之一的红色陆相泥岩、粉砂岩和砂岩互层。该地层的平均厚度为120 m。硅塑性红层产生了PTNM形成的痕迹化石。Voigt等人。(2013)最近认为,这些沉积物是在干湿交替的条件下在沿海洪泛区形成的。他们基于详细的沉积学和技术分析得出了这一结论,这些分析表明,在Robledo山脉组红层中发现的大多数痕迹化石都保存在远端裂缝-展纹粉砂岩到细粒砂岩的泥覆表面上。在他们的研究中记录的物理和生物结构支持淡水生态系统为主的重建
{"title":"Gallery of Geology: Permian Angular Uncomformity, Robledo Mountains, Dona Ana County, New Mexico","authors":"S. Lucas, W. Nelson","doi":"10.58799/nmg-v37n1.21","DOIUrl":"https://doi.org/10.58799/nmg-v37n1.21","url":null,"abstract":"During the late Paleozoic (Pennsylvanian–Early Permian), the collision of Gondwana and Laurussia (Euramerica) created the Pangean supercontinent . That collision caused extensive tectonism along a then nearly equatorial zone that extended from eastern Europe to western North America . In the United States, from Illinois to Idaho, the Ancestral Rocky Mountains (ARM) formed as a lengthy belt of basement-cored uplifts (e .g ., Kluth and Coney 1981; McBride and Nelson 1998; Dickinson and Lawton 2003) . In New Mexico, these uplifts were mostly north-south oriented islands surrounded by shallow seas during the Pennsylvanian that were ultimately worn down and buried by alluvial sediments during the Early Permian (Woodward et al . 1999) . Deciphering many aspects of ARM tectonism in New Mexico has been difficult because few late Paleozoic structures are preserved intact (e .g ., Woodward et al ., 1999) . Indeed, most of these structures were reactivated by tectonism during the Late Cretaceous–Eocene Laramide orogeny or during the late Cenozoic tectonism associated with Basin and Range extension, notably of the Rio Grande rift . Perhaps the best documented ARM structures are those described by Bachman and Hayes (1958), Pray (1961) and others in the Sacramento Mountains of Otero County, where folded Pennsylvanian strata are truncated by nearly flat lying Permian red beds . Here, we document a small ARM structure in the southern Robledo Mountains of Doña Ana County . This structure is within the confines of the Prehistoric Trackways National Monument (PTNM) . The PTNM is approximately 2,137 hectares (5,280 acres) of land protected by an act of the U . S Congress primarily because of its world-class Early Permian trace-fossil assemblages (Lucas et al . 2011) . The trace fossils come from a lithostratigraphic unit referred to as the Robledo Mountains Formation of the Hueco Group (termed Abo Tongue or Abo Member of the Hueco Formation in older stratigraphic terminology, Seager et al ., 2008) . In the PTNM, the Robledo Mountains Formation is composed of approximately two-thirds drab-colored marine limestone and shale interbedded with one-third red terrestrial mudstone, siltstone and sandstone . The formation has an average thickness of 120 m . The siliciclastic red beds yield the trace fossils for which the PTNM was created . Voigt et al . (2013) recently argued that these sediments formed on a coastal floodplain during alternating wet and dry conditions . They based this conclusion on detailed sedimentological and ichnological analysis that indicates most of the trace fossils found in the Robledo Mountains Formation red beds were preserved on mud-draped surfaces within distal crevasse-splay siltstone to fine-grained sandstone . The physical and biological structures recorded in their study support the reconstruction of a freshwater ecosystem dominated","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":"71176428","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}
In the 1920s the coal-mining settlement of Tokay, Socorro County, New Mexico (Fig. 1), was a bustling town of a few hundred inhabitants, including 125 coal miners (Julyan, 1996, p. 356). Tokay was on the southwest side of the Carthage coal field, about 10 miles east of San Antonio, New Mexico. See map in Hook and Cobban 2015 (this volume, p. 27). Among more than 50 frame structures Tokay boasted a single two-story building that had a pool hall/ barbershop/bar on the first floor and a school for grades 1-5 on the second. A staircase on the outside of the building allowed the students to go to school without having to pass through the bar first. A power plant on the north end of town provided electricity for Tokay; it billows smoke both in the postcard (Fig. 1) and in the 1927 oil painting of the town (cover and Fig. 2B). A combination general store/post office/mine office on the north side of the camp provided supplies for the miners and their families. The settlement had no bank, so the miners were paid partly in script or trade tokens in various denominations that could be redeemed at the store. The general store stocked the case of Tokay grapes that gave the town its name in 1917 (Anonymous, 1968). The original town was established in 1915 by Bartley H. Kinney, who later served as President of the board of Regents of the New Mexico School of Mines. Mr. Kinney, a mining engineer, organized the San Antonio Coal Company to mine coal in the southwest portion of the Carthage coal field. During the first year or two of its existence, the town had no formal, i.e., no federally recognized, name. The Post Office Department had rejected many names for the town, including the name “Kinney,” which it found to be in conflict. One day, according to Julyan (1996, p. 356), “... while Kinney and a postal inspector were discussing names in the community’s general store, Kinney looked at a case of Tokay grapes on the counter and asked, “How about Tokay?” The inspector agreed and the town of Tokay was born, named for a very sweet grape and wine that had nothing to do with coal mining. Tokay had a post office from 1917 until 1932. Mining ceased in the late 1940s, when most of the town’s frame buildings were moved to Socorro. However, during Tokay’s heyday, the plaza between the school house and general store (Figs.1 and 3) was used for festivals and celebrations; three major holidays—Mexico’s 1862 victory over France (Cinco de Mayo), U.S. Independence Day (July 4th), and Mexican Independence Day (Sixteenth of September)—were celebrated with explosions of miners’ firecrackers (sticks of dynamite). The married miners and their families lived in four rows of six frame houses on either side of the plaza (Fig. 3). A physician lived and worked in town. A small Catholic mission, part of the San Marcial Parish, was located on the south end of the settlement, as was a windmill that was the water source for the camp’s boilers and industrial use. A well about a mile south of
20世纪20年代,新墨西哥州索科罗县托凯的煤矿定居点(图1)是一个繁华的小镇,只有几百名居民,其中包括125名煤矿工人(Julyan, 1996, p. 356)。托凯位于新墨西哥州圣安东尼奥以东约10英里的迦太基煤田的西南侧。参见Hook and Cobban 2015中的地图(本卷第27页)。在50多个框架结构中,Tokay拥有一座两层的建筑,一楼有台球厅/理发店/酒吧,二楼有1-5年级的学校。建筑外面的楼梯让学生不必先经过酒吧就可以上学。小镇北端的一座发电厂为Tokay提供电力;在明信片(图1)和1927年的油画《小镇》(封面和图2B)中,它都是滚滚的烟雾。营地北侧的综合杂货店/邮局/矿务局为矿工及其家属提供物资。该定居点没有银行,因此矿工的部分报酬是手稿或各种面额的交易代币,这些代币可以在商店兑换。杂货店里摆放着一箱箱的Tokay葡萄,正是这些葡萄使这个小镇在1917年得名(Anonymous, 1968)。最初的小镇是由Bartley H. Kinney于1915年建立的,他后来担任新墨西哥矿业学院董事会主席。Kinney先生是一名采矿工程师,他组织了圣安东尼奥煤炭公司,在迦太基煤田的西南部分开采煤炭。在它存在的头一两年里,这个城镇没有正式的,也就是说,没有联邦承认的名字。邮政署拒绝给这个小镇取很多名字,其中包括“金尼”这个名字,因为它发现这个名字有冲突。有一天,根据Julyan (1996, p. 356),“……当金尼和邮政检查员在社区杂货店讨论名字时,金尼看了看柜台上的一箱托凯葡萄,问道:“托凯怎么样?”检查员同意了,于是Tokay镇诞生了,它以一种非常甜的葡萄和葡萄酒命名,而这种葡萄和葡萄酒与煤矿开采无关。从1917年到1932年,东京有一个邮局。20世纪40年代末,当该镇的大部分框架建筑搬到索科罗时,采矿停止了。然而,在Tokay的全盛时期,校舍和杂货店之间的广场(图1和3)被用于节日和庆祝活动;三个主要的节日——1862年墨西哥战胜法国(五月五日节)、美国独立日(7月4日)和墨西哥独立日(9月16日)——都是用矿工的鞭炮(炸药棒)来庆祝的。已婚的矿工和他们的家人住在广场两侧的四排六栋框架房子里(图3)。一位医生在镇上生活和工作。一个小型的天主教传教会,是圣马西尔教区的一部分,位于定居点的南端,那里有一个风车,是营地锅炉和工业使用的水源。营地以南约一英里处的一口井提供饮用水。托凯镇的详细资料(图3)来自特朗西托·迪亚兹(1915-1990),他是托凯的长期居民,1920年从墨西哥哈利斯科州搬到这里。Bartley H. Kinney(1884-1959),迦太基燃料公司的前主管,于1915年创立了Tokay,当时他在新墨西哥州索科罗县新墨西哥子午线T. 5 S. R. 2 E.位于新墨西哥子午线SW1/4 NE1/4和W1/2 SE1/4段8和NW1/4 NE1/4段17的迦太基煤田西南侧拥有160英亩的土地。在海拔5055英尺的地方,Tokay坐落在一个台地上,下面是坚韧的更新世Sierra Ladrones地层。高产的金尼1号和4号矿位于定居点东南约半英里处。主煤层厚达5英尺,位于Crevasse Canyon组Dilco煤段的基底部分,距其与Gallup砂岩的接触面25英尺左右(Hook 2010,图6)。采煤是一项艰苦而危险的工作。矿工的工资通常是根据他们填煤车的数量计算的;通常每班六到七辆车。出生在托凯的露丝·金尼·甘纳韦(Ruth Kinney Gannaway, 2015年5月5日)在她关于托凯和迦太基煤田生活的纪念品剪贴簿中,讲述了用来记录哪位矿工在某一天工作的系统。在进入矿井之前,每个矿工都从办公室的钉板上拿了一个“垫圈”,也被称为“矿工的黄铜”,上面写着他唯一的号码。换班结束时,他把洗衣机放回挂板上。通过这种方式,金尼先生可以确保一天结束时没有人留在矿井里。从1915年到1927年,随着金尼先生开了更多的煤矿,Tokay的煤炭产量稳步增长。然而,在20世纪20年代后期,大萧条和用于供暖和发电的低成本燃油和天然气的引入造成了损失(Hoffman和Hereford, 2009, p. 412)。 Tokay在1928年失去了与El Paso Gas和Electric Company的主要合同,被El Paso Natural Gas Company抢走;这种损失使Tokay从一个铁路服务的城镇变成了一个卡车服务的城镇(Anonymous, 1968)。商业采矿在20世纪40年代末停止。1949年,肯尼先生把土地和房子卖给了迪安·费特夫妇。Kinney先生原来的房子至今仍被用作菲特牧场总部(图3)。Tokay这个名字作为新墨西哥州煤矿开采历史的遗产和上白垩纪曼科斯页岩的一个舌的正式地层名称而流传下来(本卷,第27 - 46页)。
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A well-worn cliché tells us that “a picture is worth a thousand words,” but in the case of Audley Dean Nicols’ panorama a mere thousand is woefully insufficient to do it justice. The story of how artist Nicols came to create his masterpiece is found elsewhere in this volume; the following are descriptions of the principal features that can be observed or, in one case, almost observed, from Nichols’ vantage point just east of Tokay, New Mexico. These include, from left to right, the New Mexico Midland Railway, Magdalena Range, Socorro Peak, and the “M” on Socorro Peak. The mining camp of Tokay, visible at far left and major focal point for Nichols, is described elsewhere in this volume.
{"title":"Audley Dean Nicols' Tokay Panorama of 1927","authors":"R. Eveleth","doi":"10.58799/nmg-v37n2.52","DOIUrl":"https://doi.org/10.58799/nmg-v37n2.52","url":null,"abstract":"A well-worn cliché tells us that “a picture is worth a thousand words,” but in the case of Audley Dean Nicols’ panorama a mere thousand is woefully insufficient to do it justice. The story of how artist Nicols came to create his masterpiece is found elsewhere in this volume; the following are descriptions of the principal features that can be observed or, in one case, almost observed, from Nichols’ vantage point just east of Tokay, New Mexico. These include, from left to right, the New Mexico Midland Railway, Magdalena Range, Socorro Peak, and the “M” on Socorro Peak. The mining camp of Tokay, visible at far left and major focal point for Nichols, is described elsewhere in this volume.","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":"71177735","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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