7,335 research outputs found

    Bennett Reimer Papers

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    Bennett Reimer (born 1932), a wind player, music educator and noted author, held the John W. Beattie Endowed Chair in Music position at Northwestern University where he was Chair of Music Education Department, Director of the Ph.D Program in Music Education, and founder and Director of the Center for the Study of Education and the Musical Experience.The collection consists of published books and accompanying materials, unpublished works, journal articles, guest lecture materials and drafts of speeches given by Reimer, and materials related to books Reimer published for Silver-Burdett Music. This collection is unprocessed; an inventory is available upon request

    Bennett Reimer and MEJ: a 58-Year Partnership

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    This article focuses on the contributions made by composer Bennett Reimer to the "Music Educators Journal." It mentions the articles written by Reimer which were published in the June-July 1956 issue, the number of articles published by Reimer in the journal and Reimer's contribution to music education.Author accepted manuscript version of the article published in: Freer, P. K. (2014). Bennett Reimer and MEJ: a 58-Year Partnership. Music Educators Journal, 100(3), 24. doi: 10.1177/0027432113519417</p

    Reimer, P.

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    Antipathozoanthus hickmani Reimer & Fujii 2010, sp. n.

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    Antipathozoanthus hickmani sp. n. urn:lsid:zoobank.org:act: BC6BFB57-105C-4EC4-AEF4-87CC8B33DBDE Figures 1, 5, 7, 9, Tables 1, 2, 3 Etymology. Named after Dr. Cleveland Hickman, Jr., who graciously invited the first author to the Galápagos, and collected the first specimens of this new species. Noun in the genitive case. Material examined. Type locality: Ecuador, Galapagos: Floreana I., La Batielle, 1.2904°S 90.4989°W. Holotype: Specimen number MHNG-INVE-67495. Colony of approximately 40 polyps connected by well-developed coenenchyme on two branches of Antipathes galapagensis Diechmann, 1941 branches. Both branches approximately 7 cm long. Polyps approximately 1.5–4.0 mm in diameter, and approximately 1.0–6.0 mm in height from coenenchyme. Coenenchyme covers branches of antipatharian. Polyps and coenenchyme sand encrusted, cream-yellow in color. Collected from La Batielle, Floreana I., Galapagos, Ecuador, at 31.4 m by A. Chiriboga (AC), March 13, 2007. Preserved in 99.5% ethanol. Paratypes (all from Galapagos, Ecuador): Paratype 1. Specimen number CMNH-ZG 05883. Collected from Roca Onan, Pinzon I., at 27 m by AC, March 14, 2007. Figure &lcedil;. Antipathozoanthus hickmani sp. n. in situ in the Galapagos. a holotype MHNG-INVE-67495 showing the entire colony covering an Antipathes galapagensis, with living antipatharians visible in the background. Image by Angel Chiriboga (AC) b specimen MISE 441 at Don Ferdi, Bainbridge Rocks, Santiago I., at 23 m by JDR, March 9, 2007 c and d specimen MISE 474, Roca Onan. Pinzon I., at 35 m by AC. All scale bars: 1 cm except in a (10 cm). Paratype 2. Specimen number USNM 1134064. Collected from Cousins Rock, at 28 m by James D. Reimer (JDR), March 10, 2007. Other material (all from Galapagos, Ecuador): MISE 03-221, Cousins Rock, at 12 m by AC on October 9, 2003; MISE 03-539, Cousins Rock, at 20 m by CH on November 11, 2003; MISE 03-549, Cousins Rock, at 23 m by CH on November 11, 2003; MISE 04-341, Elizabeth Bay, Isabela I., at 25 m by G. Edgar (GE) on December 2, 2003; MISE 440, Don Ferdi, Bainbridge Rocks, at 22 m by JDR, March 9, 2007; MISE 441, Don Ferdi, Bainbridge Rocks, at 23 m by JDR, March 9, 2007; MISE 444, Cousins Rock, Galapagos, Ecuador, at 21 m JDR, March 10, 2007; MISE 474, La Batielle, Floreana I., at 35 m by AC, March 14, 2007. Sequences. See Table 1. Description. Size: Polyps in situ approximately 4–12 mm in diameter when open, and approximately 4–15 mm in height. Morphology: Antipathozoanthus hickmani has approximately 40 bright yellow and/ or red tentacles, with long red, yellow, or cream-colored polyps that extend well clear of the coenenchyme (Figure 1). Tentacles are almost always longer than the expanded oral disk diameter. Cnidae: Basitrichs and microbasic p-mastigophores (often difficult to distinguish), holotrichs (large and medium), spirocysts (see Table 2, Figure 9). Table &lcedil;. Examined zoanthid specimens for new species from the Galapagos Islands, and GenBank Accession Numbers. NA = not available or data not acquired. aSpecimens with the designations such as 03-560 are from 2001-2004 surveys (see Reimer et al. 2008b). Other specimens are from 2007 and have either specimen numbers (e.g. 471) in JDR’s collection, or museum type specimen numbers as given. Abbreviations: USNM: National Museum of Natural History, Smithsonian Institution, Washington, D.C., USA, CMNH: Chiba Prefectural Natural History Museum, Japan, MHNG: Natural History Museum of Geneva, Switzerland, MISE: Molecular Invertebrate Systematics and Ecology Laboratory, University of the Ryukyus, Nishihara, Okinawa, Japan. bLatitude and longitude values that are negative represent South and West values respectively, while positive values (latitude only) represent North values. cCollector abbreviations: CH = C. Hickman, Jr., LV = L. Vinueza, AC = A. Chiriboga, GE = G. Edgar, JDR = JD Reimer, RP = R. Pepolas, FL = F. Liss, BR = B. Riegl, DR = D. Ruiz, FR = F. Riveiria, OB = O. Breedy, MV = M. Vera. Differential diagnosis. Differs from Antipathozoanthus macaronesicus (Ocaña & Brito, 2004) (with regards to distribution; Galapagos as opposed to Cape Verde), coloration (no red or cream colors observed in A. macaronesicus), substrate (Antipathes galapagensis as opposed to Tanacetipathes cavernicola Opresko, 2001). Other morphologically similar and undescribed zoanthids (epizoic on antipatharians, similar sizes, yellowish in color) have been recorded from Madagascar and Japan (specimens in JDR’s collection), although these other specimens were found on different antipatharian species than Antipathozoanthus hickmani, and were never red or cream in color. Antipathozoanthus hickmani is the only zoanthid in the Galápagos found on living Antipathes galapagensis (Table 3). Habitat and distribution. All collected samples from Galapagos were on the black coral Antipathes galapagensis, at depths of 12 m to 35 m. Although A. galapagensis is found throughout the archipelago, Antipathozoanthus hickmani colonies were observed only at Santiago, Floreana, Isabela and Pinzon Islands, and it may be that this genus has a patchy distribution in the Galápagos. A. hickmani is potentially also found at Isla del Coco (Costa Rica) on the same antipatharian species, based on Museo de Zoologia, University of Costa Rica specimen UCR 827, although this has yet to be confirmed with detailed examinations. Biology and associated species. Antipathozoanthus hickmani may cover only a portion of a living Antipathes galapagensis black coral colony, or cover the entire colony, suggesting this species may be parasitic. Some A. hickmani specimens were found on completely dead A. galapagensis colonies or branches. Notes. Previously mentioned in Reimer et al. (2008b, 2010) and Hickman (2008) as Parazoanthus sp. G1.Published as part of Reimer, James & Fujii, Takuma, 2010, Four new species and one new genus of zoanthids (Cnidaria, Hexacorallia) from the Galapagos Islands, pp. 1-36 in ZooKeys 42 (42) on pages 6-14, DOI: 10.3897/zookeys.42.378, http://zenodo.org/record/57665

    Nanozoanthus Fujii & Reimer 2013, GEN. NOV.

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    NANOZOANTHUS GEN. NOV. &lt;p&gt; &lt;i&gt;Type species&lt;/i&gt;&lt;/p&gt; &lt;p&gt; &lt;i&gt;Nanozoanthus harenaceus&lt;/i&gt; sp. nov.&lt;/p&gt; &lt;p&gt; &lt;i&gt;Etymology&lt;/i&gt;&lt;/p&gt; &lt;p&gt; Named from the latin &lsquo;nano&rsquo;, meaning &lsquo;dwarf &rsquo;, as polyp size in specimens of this group are generally too small to clearly observe &lt;i&gt;in situ&lt;/i&gt; with the naked eye, with ending as in other zoanthid genera. Gender is masculine.&lt;/p&gt; &lt;p&gt; &lt;i&gt;Diagnosis&lt;/i&gt;&lt;/p&gt; &lt;p&gt;Only one genus of family Nanozoanthidae, as for family above.&lt;/p&gt;Published as part of &lt;i&gt;Fujii, Takuma &amp; Reimer, James Davis, 2013, A new family of diminutive zooxanthellate zoanthids (Hexacorallia: Zoantharia), pp. 509-522 in Zoological Journal of the Linnean Society 169 (3)&lt;/i&gt; on page 512, DOI: 10.1111/zoj.12075, &lt;a href="http://zenodo.org/record/4890473"&gt;http://zenodo.org/record/4890473&lt;/a&gt

    Interview of John David Reimer by Raimund E. Goerler

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    1. Captain Finn Ronne p. 4, 5, 6 2. Dr. Vivian Fuchs p. 5, 6, 20 3. Admiral Dufek p. 11, 15, 18, 19, 20, 30 4. Reverend Doctor Lanahan p. 13 5. Sir Edmond Hillary p. 20 6. Admiral Tyree p. 24 7. Admiral Bupers p. 26 8. Lieutenant Riley p. 26 9. Werner Von Braun p. 29The media can be accessed here: http://streaming.osu.edu/knowledgebank/byrd/oral_history/John_Reimer.mp3Mr. Reimer developed an interest in nautical things while he was a Boy Scout. After graduating from high school, he joined the Navy and completed over 26 years of service. He became interested in photography at the Aviation Fundamental School. As a member of VX6, he was assigned to an ice breaker. He produced a pictorial history of life on the ship. After arriving in Antarctica in 1956, he assisted in construction of a base. He photographed the items that the marine biologists removed from Weddell Sea. During the 1957 trip, he did aerial mapping of the mountain ranges around McMurdo. The cameras were not designed for cold weather. The cameras operated satisfactorily after the lubricants were removed. A seismologist had him photograph seismology tests at the South Pole to determine the thickness of the ice cap. Another mission involved aerial mapping of crevasses on tractor trains routes. The equipment used in aerial mapping and the procedures are described. During the 1958-59 season, he photographed the opening of the season—supplies and people arriving and winter crew leaving. The delivery of a new bulldozer to Byrd station resulted in some nice still photographs. The plane’s crew identified another mountain range while aerial mapping the Sentinel Mountains in 1959-1960. While at Byrd Station, he was advanced to chief photographer’s mate. During the 1960-61 seasons, he did more aerial mapping. On one trip, a large deposit of coal was identified. In summary, Mr. Reimer comments on the interactions between scientists and the Navy personnel. After 3 years at NAS Norfolk, he was assigned chief in charge of the photo lab on USS America CVA66. After being made chief in charge of VDX6 photo division, he returned to Antarctica during Operation Deep Freeze 66. He had a similar assignment with Deep Freeze 68. Major Topics 1. Mr. Reimer’s Boy Scouts led him eventually to join the Navy. 2. In 1956, he was assigned to the photo group on the Icebreaker Staten Island, to make a pictorial history of the crew. 3. The building of Ellsworth Station is described. 4. His assignment included both still and motion photography, and aerial photography. 5. On the trip to Antarctica, he photographed sea organisms collected by the marine biologist. 6. In 1957, John did aerial mappings of the mountain range around McMurdo. 7. Mr. Reimer listed operational problems with photographic equipment in a cold climate in 1957-1958. 8. Another project included aerial mapping of crevasse fields. 9. The equipment and flight procedures for aerial mapping are described in detail. 10. In 1958-59, his work included photographing the aerial drops of bulldozers. 11. In 1959-60, while photographing the Sentinel Mountains, they identified another group of mountains. 12. In November 1961, he was advanced to chief photographer’s mate and describes the initiation ceremony. 13. During Deepfreeze 61, he helped geologists photograph a coal deposit. Later, he married a New Zealand girl. 14. The interactions between civilian scientists and the navy personnel are described. 15. John returned to Antarctica during Operation Deepfreeze 66, and again in Deepfreeze 68. 16. Highlights of his career included making chief petty officer, and having a mountain named for him.Funded by a grant from the National Science Foundation

    Nanozoanthidae Fujii & Reimer 2013, FAM. NOV.

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    NANOZOANTHIDAE FAM. NOV. &lt;p&gt; &lt;i&gt;Type genus&lt;/i&gt;&lt;/p&gt; &lt;p&gt; &lt;i&gt;Nanozoanthus&lt;/i&gt; gen. nov.&lt;/p&gt; &lt;p&gt; &lt;i&gt;Etymology&lt;/i&gt;&lt;/p&gt; &lt;p&gt;As for the type genus, with ending as in other zoanthid families.&lt;/p&gt; &lt;p&gt; &lt;i&gt;Diagnosis&lt;/i&gt;&lt;/p&gt; &lt;p&gt; Well-developed polyps connected by narrow stolon. Mineral particles encrusted in column from aboral end to the edge of the oral disc. Irregularly sized sand particles encrusted into ectoderm and slightly into mesoglea. Zigzagged, white-coloured pattern following outside edge of oral disc. Macrocnemic mesenterial arrangement. Sphincter muscle mesogleal. No lacunae or ring sinus. Zooxanthellate. Mitochondrial &lt;i&gt;COI&lt;/i&gt; and &lt;i&gt;16S&lt;/i&gt; ribosomal DNA sequences significantly differ from all other known zoanthid genera (Figs 1, 2).&lt;/p&gt; &lt;p&gt; &lt;i&gt;Remarks&lt;/i&gt;&lt;/p&gt; &lt;p&gt; Only a few other macrocnemic zoanthids symbiotic with zooxanthellae are known, primarily from the genera &lt;i&gt;Parazoanthus&lt;/i&gt; and &lt;i&gt;Isozoanthus&lt;/i&gt;. It is easy to distinguish this family from these two genera by the position of sphincter muscle and by the phylogenetically highly divergent &lt;i&gt;COI&lt;/i&gt; and mt &lt;i&gt;16S&lt;/i&gt; rDNA sequences.&lt;/p&gt;Published as part of &lt;i&gt;Fujii, Takuma &amp; Reimer, James Davis, 2013, A new family of diminutive zooxanthellate zoanthids (Hexacorallia: Zoantharia), pp. 509-522 in Zoological Journal of the Linnean Society 169 (3)&lt;/i&gt; on page 512, DOI: 10.1111/zoj.12075, &lt;a href="http://zenodo.org/record/4890473"&gt;http://zenodo.org/record/4890473&lt;/a&gt

    Managing the Legal Risk in Providing Online Quality Certification Services in EU

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    Balboni, P. (2005) Managing the Legal Risk in Providing Online Quality Certification Services in EU. In S. Paulus, N. Pohlmann, &amp; H. Reimer (eds.), ISSE 2005 Securing Electronic Business Processes, Vieweg, Wiesbaden, 189 – 20

    Debates over Palaeolithic chronology - the reliability of C-14 is confirmed

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    The debate about the complex issues of human development during the Middle to Upper Palaeolithic transition period (45-35 ka BP) has been hampered by concerns about the reliability of the radiocarbon dating method. Large C-14 anomalies were postulated and radiocarbon dating was considered flawed. We show here that these issues are no longer relevant, because the large anomalies are artefacts beyond plausible physical limits for their magnitude. Previous inconsistencies between C-14 radiocarbon datasets have been resolved, and a new radiocarbon calibration curve, IntCal09 (Reimer et al., 2009), was created. Improved procedures for bone collagen extraction and charcoal pre-treatment generally result in older ages, consistent with independently dated time markers. (C) 2012 Elsevier Ltd. All rights reserved.</p

    Microzoanthus Fujii & Reimer 2011

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    Genus &lt;i&gt;Microzoanthus&lt;/i&gt; Fujii &amp; Reimer, 2011 &lt;p&gt; Type species. &lt;i&gt;Microzoanthus occultus&lt;/i&gt; Fujii &amp; Reimer, 2011, by original designation.&lt;/p&gt; &lt;p&gt; &lt;b&gt;Diagnosis.&lt;/b&gt; Identical to Microzoanthidae (diagnosis of Fujii &amp; Reimer 2011). Colonial Microzoanthidae free-living and lacking a scleroprotein skeleton. Known from temperate and tropical cryptic habitats in the Pacific Ocean at 0&ndash; 23 m. Azooxanthellate. Polyps transparent or faintly red, expand to 3 mm wide and 10 mm long. Capitular ridges largely imperceptible because of heavy encrustations. Oral disk calathiform and edged in a distinct zig-zag pattern (diagnosis expanded using data from Fujii &amp; Reimer 2011). Marginal musculature endodermal, 268&ndash;331 &Mu;m in length, composed of 10&ndash;16 attachment points. Encrustations of column through ectoderm but not penetrating ectodermal surface of the mesoglea; elliptical lacunae just beneath ectodermal surface of mesoglea form an encircling sinus (diagnosis expanded using data presented here).&lt;/p&gt; &lt;p&gt; &lt;b&gt;Remarks.&lt;/b&gt; The phylogenetic position of &lt;i&gt;Microzoanthus&lt;/i&gt;, as inferred by mitochondrial cytochrome oxidase (COI) and 16s ribosomal (mt 16S rDNA) genes (see Fujii &amp; Reimer 2011; Figs 7 &amp; S1), is near the base of the Zoanthidea and as the sister clade to &lt;i&gt;Isozoanthus&lt;/i&gt; (in the COI tree) or all Zoanthidea except &lt;i&gt;Isozoanthus&lt;/i&gt; (in the 16S tree). Although these phylogenies are incongruent (with each other and other published hypotheses, &lt;i&gt;e.g.&lt;/i&gt;, Sinniger &lt;i&gt;et al.&lt;/i&gt; 2005, Swain 2010) and poorly supported (both problems may be resolved by multigene analysis applied to comprehensive taxon sampling), they suggest that &lt;i&gt;Microzoanthus&lt;/i&gt; may occupy a critical position near the origin of Zoanthidea and could provide insight into the evolution of &lt;i&gt;Isozoanthus&lt;/i&gt; and clarify relationships between the genera of Zoanthidea.&lt;/p&gt;Published as part of &lt;i&gt;Swain, Timothy D. &amp; Swain, Laura M., 2014, Molecular parataxonomy as taxon description: examples from recently named Zoanthidea (Cnidaria: Anthozoa) with revision based on serial histology of microanatomy, pp. 81-107 in Zootaxa 3796 (1)&lt;/i&gt; on page 99, DOI: 10.11646/zootaxa.3796.1.4, &lt;a href="http://zenodo.org/record/251140"&gt;http://zenodo.org/record/251140&lt;/a&gt
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