4,880 research outputs found
Personal Papers (MS 80-0002)
Letter from Mary T. Steyn of The Readers Digest to Daniel W. Kempner providing some information on the author of an article he was asking about
Panaqolus nix Cramer & Py-Daniel 2015, new species
Panaqolus nix, new species u r n:l s i d:z o o b a n k.o r g:a c t: 42F632 D 8-A127- 4 0 9 2 -B0 9B - 708882C0C3B9 (Figs. 1-5) Panaque sp. 1: photo - Zawadzki & Chamon, 2013: p. 312. Panaque sp. 2: UFRO-I 6384, Zawadzki & Chamon, 2013: p. 313 (see remarks for further explanation). Holotype. INPA 39606, male, 110.1 mm SL, Brazil, Rondônia, rio Madeira, cofferdam at construction site of Santo Antônio hydroelectric power plant (former Santo Antônio rapids), 08°48’06”S 63°57’00”W, 14 Feb 2012, C. A. Cramer. Paratypes. 48 specimens. Brazil: Rondônia State: INPA 39605, 3, 54.6-73.7 mm SL, Mamoré, near the São Lourenço community, trawl net fishing, 11°43’24.10”S 65°11’31.70”W, 30 May 2010, L. H. Rapp Py-Daniel. INPA 41148, 2, 95.3 and 96.8 mm SL, rio Karipunas near mouth, 09°11’46.6”S 64°37’20.7”W, 4 Oct 2010, NaturaeEnvironmentalCompany technicians. INPA 41149, 1, 85.0 mm SL, rio Madeira, near mouth of rio Karipunas, 09°12’18.9”S 64°37’08.4”W, 30 Oct 2010, Naturae Environmental Company technicians. INPA 41150, 28, 32.8-112.2 mm SL, rio Madeira, cofferdam at the construction site of Jirau hydroelectric power plant (former Jirau rapids), 09°15’15.7”S 64°38’50.4”W, 11-13 Nov 2011, Naturae Environmental Company technicians. MZUSP 114009, 3, 68.5-76.2 mm SL; UFRO-I 6384, 5, 50.8- 80.7 mm SL, same data as INPA 39605. UFRO-I 7968, 1, 81.4 mm SL, rio Madeira, near Ilha do Búfalo, trawl net fishing, 09°08’51.10”S 64°32’33.70”W, 23 Oct 2010, A. Ribeiro. UFRO-I 9974, 1, 53.6 mm SL, rio Madeira, below Santo Antônio rapids, trawl net fishing, 08°46’36.11”S 63°55’26.09”W, 23 Jul 2011, L. Nogueira. UFRO-I 10050, 1, 90.4 mm SL, same data as INPA 39605. UFRO-I 13039, 1, 49.5 mm SL, same locality as holotype, 1 Dec 2011, C. A. Cramer. UFRO-I 13040, 1, 57.7 mm SL, same data as UFRO-I 13039. UFRO-I 19646, 1, female, 97.3 mm SL, same data as holotype. Non-types. 1 specimen. Peru: ROM 92440, 1, 117.0 mm SL, Río Tambopata, Madre de Dios drainage, approximately 12°48’S 69°17’W, 16 Aug 2010, K. Roach and A. Jackson. Diagnosis. The presence of small white dots on the whole body and fins distinguish Panaqolus nix from all congeners except P. albomaculatus. These dots are frequently faded in preserved specimens (typically, at least the dorsal and caudal fins show some traces of dots). Panaqolus nix can be distinguished from P. albomaculatus by having more dots on the trunk (on nearly all plates having one dot each vs. one dot each on less than half of the plates), a longer head-eye length (35.1-41.5% HL [mean 37.8] vs. 31.9-37.2% HL [mean 34.4]), a smaller orbital diameter (12.5-16.8% HL [mean 14.3] vs. 16.0-19.9% HL [mean 17.7]), and longer rictal barbels (9.7-19.6% HL [mean 13.8] vs. 1.6-8.9% HL [mean 4.9]). Only two other Panaqolus species (P. dentex and P. koko) lack alternating dark and light bands on fins. Panaqolus nix can be distinguished from P. dentex by lacking lighter colored saddles (vs. three lighter colored saddles between dorsal-fin origin and caudal fin), by having a shorter head-pectoral length (22.4-28.2% SL [mean 25.5] vs. 27.2-38.1% SL [mean 29.2]), a lower caudal peduncle depth (9.3-11.4% SL [mean 10.5] vs. 11.0-13.3% SL [mean 12.2]), a smaller orbital diameter (12.5-16.8% HL [mean 14.3] vs. 16.4-22.8% HL [mean 17.8]), and a larger adult body size (more than 100 mm SL vs. less than 80 mm SL). Panaqolus nix differs from P. koko in the shape of the main tooth cusp (round and without or with very small lateral cusp vs. quadrangular and with strong lateral cusp), a smaller orbital diameter (12.5-16.8% HL vs. 18.9-20.8% HL [n=7]), and a larger interorbital width (34.3-39.3% HL vs. 29.4- 33.2% HL). Panaqolus albivermis typically has alternating light bands and rows of light dots or short lines on its body. Panaqolus nix can be separated from this species by having a shorter dorsal spine (26.2-32.5% SL vs. 33.0-36.0% SL [n=4]), a shallower caudal peduncle (9.3-11.4% SL vs. 12.2- 14.9% SL [n=4]), and a higher adipose-anal depth (17.9- 22.2% SL vs. 15.8-17.9% SL [n=4]). Panaqolus changae, P. gnomus, P. maccus, P. nocturnus, and P. purusiensis have alternating dark and light bands on the body (except P. nocturnus and adult P. purusiensis) and fins (vs. never showing bands on body or fins in P. nix). Further, P. nix can be distinguished from P. changae by a narrower ventral cleithral width (29.0-33.8% SL [mean 31.0] vs. 33.4-37.4 [mean 34.8), a shorter head-pectoral length (22.4-28.2% SL [mean 25.5] vs. 28.0-31.1% SL [mean 29.9), a smaller orbital diameter (12.5-16.8% HL [mean 14.3] vs. 16.2-20.9% HL [mean 18.2]), and a larger adult body size (more than 100 mm SL vs. less than 90 mm SL). Panaqolus nix differs from P. gnomus by a lower dorsal-pectoral depth (26.9- 30.3% SL [mean 28.6] vs. 30.3-36.8% SL [mean 32.9]), a smaller interorbital width (34.4-39.3% HL vs. 39.7-44.7% HL), and a larger adult body size (more than 100 mm SL vs. less than 80 mm SL). Panaqolus nix can be separated from P. maccus by a shorter predorsal length (40.1-44.5% SL [mean 42.3] vs. 44.3-49.2% SL [mean 46.0), a shorter headpectoral length (22.4-28.2% SL [mean 25.5] vs. 27.2-44.1% SL [mean 30.8]), and a larger adult body size (more than 100 mm SL vs. less than 90 mm SL). Panaqolus nix can be distinguished from P. nocturnus by the angle of dentary tooth rows (less than 50° to nearly parallel vs. approximately 70°). Panaqolus nix differs from P. purusiensis by having a lower dorsal-pectoral depth (26.9-30.3% SL [mean 28.6] vs. 29.8-32.9% SL [mean 30.9;]), a lower caudal peduncle depth (9.3-11.4% SL [mean 10.6] vs. 10.9-14.0% SL [mean 12.1]), and a smaller mouth width (34.4-46.4% HL [mean 39.9] vs. 41.6-50.3% HL [mean 44.1]). Description. Counts and proportional measurements in Table 1. Medium-sized loricariid with standard length of measured specimens up to 112.2 mm SL. Dorsal profile of head and snout strongly convex from snout tip to posterior tip of supraoccipital, straight and posteroventrally slanted between dorsal-fin origin and adipose-fin origin, gently concave through caudal peduncle to posterior tip of procurrent caudal-fin ray. Dorsal orbit margin only slightly raised, forming gentle ridge, narrowing anteriorly, from anterior orbit margin to area lateral to nares. Dorsal surface of trunk transversely flattened from dorsal-fin origin to adipose-fin base. Ventral profile of head and body flat from oral disk to anal-fin origin. Caudal peduncle oval in crosssection. Greatest body depth at dorsal-fin origin. Pectoralfin origin just posterior to orbit; pelvic-fin origin at vertical through origin of second dorsal-fin ray; anal-fin origin slightly posterior to vertical through origin of last dorsal- fin ray. Adipose fin with well-ossified leading spine bearing odontodes. Head and body covered by odontodes of uniform size and distribution. Enlarged odontodes on anterodorsal border of pectoral-fin spine. Cheek odontodes hypertrophied with anteriorly curved hooks on the tips; longest odontode extending to posterior cleithrum margin. Interorbital space flat or slightly convex. Eye dorsolaterally placed; orbit diameter 12.5-16.8% HL. Iris operculum present. Nares small and ovoid, slightly longer than wide. = standard deviation, n = number of specimens, H = holotype. Interlandmarks (ILM) are the two points between which measurements were taken (from Luj an et al., 2010). Oral disk round, maxillary barbels of moderate length (10-20% HL). Lips papillate; small patch of elongate fleshy papillae behind each dentary tooth row (Fig. 2). Border of lips smooth, without papillae. Teeth spoon-shaped and unicuspidate or with very small lateral cusp. Premaxillary teeth 3-7 per ramus (mode 4), mandibular teeth 4-7 per ramus (mode 5). Premaxillary tooth rows angled at approximately 90°, dentary tooth rows acutely angled at approximately 50° or nearly parallel (Fig. 2). small plates. Body with pronounced lateral ridge extending from cleithrum to posterior margin of fifth or sixth plate of the inframedian plate row, decreasing in prominence posteriorly. Trunk without elevated ridges. 7-8 plates on dorsal-fin base (mode 7), 5-7 plates between dorsal and adipose fin (mode 6), usually 1 azygous preadipose plate, 6-8 plates between adipose and caudal fin (mode 7), 2 plates on anal-fin base, 11-12 scutes between anal and caudal fin (mode 11), and 24-25 lateral plates (mode 25). Dorsal fin II,7-8 (holotype II,7), pectoral fin I,6, pelvic fin i,5, anal fin i,4, caudal fin i,13-14,i (holotype i,14,i). Spinelet triangular, dorsal-fin spine lock functional, posterior fin margin straight, margin of last two rays rounded. Dorsalfin origin closer to vertical line passing through pelvicfin origin than to vertical line passing through pectoralfin origin; not reaching adipose fin when adpressed. Last dorsal-fin ray without prolonged membrane. Adipose fin triangular; adipose-fin spine slanted posteroventrally, tip straight to curved ventrally, pointed; posterior margin of adipose-fin membrane concave to nearly vertical. Pectoralfin spine robust, membrane between spine and first ray without fleshy extension, distal fin margin straight. Pectoral fin, when depressed reaching 1/3 of pelvic fin. Pelvic-fin spine robust, distal margin slightly rounded, when adpressed reaching mid-length of anal fin. Caudal fin strongly forked; caudal-fin spines usually tipped with filaments of the length of the longest branched caudal-fin rays. Color in alcohol. Coloration of head, body and fins without bands or saddles. Base coloration varying from uniformly yellowish-white over light brown to dark brown or nearly black in different specimens. Small white dots (about 1/3 of the eye diameter) present on whole body and all fins; approximately one dot per plate; dots smaller on head. Dots faded to absent in preserved specimens, especially on trunk, but usually visible on fins. Caudal fin showing distinct dots or diffuse lighter markings. Head and body plated dorsally, except for small naked area around dorsal-fin base; some specimens with naked area at tip of snout. Supraoccipital bordered posteriorly by 2-3 (mode 3) plates on each side. Abdomen of adults ranging from incompletely plated (plates only in pectoral girdle, along sides, and posterior to pelvic fin) to nearly completely covered by small irregularly arranged platelets, with a small naked area around pelvic-fin origin and the urogenital orifice. Abdomen of juveniles of 70 mm SL or less naked or with only very few plates on the border with inframedian plates. Large naked area dorsally to pelvic-fin base, below ventral margin of inframedian plate row; sometimes showing 1-3 Color in life. Color of head, body and fins without bands or saddles. Base coloration varying from uniformly yellowishwhite over pale brown (Fig. 3) to dark brown or nearly black in different specimens. In an aquarium, with clear water, light colored fish become dark in few days (Fig. 4). Live specimens with small white dots (more or less 1/3 of the eye diameter) on whole body and all fins; approximately one dot per plate. Dots smaller on head. Caudal fin showing distinct dots or diffuse lighter markings. Sexual dimorphism. Mature males have longer odontodes on the pectoral-fin spine and on the caudal peduncle (Fig. 5). The illustrated specimen was dissected and its gender was confirmed based on gonads examination. A large female (UFRO-I 19646) that was kept in an aquarium did not develop any conspicuously elongated odontodes over time. Some eggs were released during the process of preservation shortly after she died in captivity. Distribution and Habitat. The known distribution of this species is the Madeira basin, including the Madeira, Mamoré, and Tambopata (Madre de Dios drainage) rivers (Fig. 6). Most of the specimens have been collected in cofferdams at the construction sites of the hydroelectric power plants of Santo Antônio and Jirau (former Santo Antônio and Jirau rapids), on the rio Madeira, by several technicians and ichthyologists hired by the two Consulting Environmental Companies responsible for the biological inventories in the area. Most of the remaining specimens have been caught in depths of 3.1 to 11 m (UFRO-I 6384, INPA 39605, MZUSP 114009) and 4.1 to 8.5 m (UFRO-I 6384) using trawl nets. This indicates that this species prefers deep-water habitats with strong current, which might help to explain its relative rarity in scientific collections. Etymology. From the Latin nix meaning snow, alluding to the color: in dark individuals the dots look like falling snowflakes, while pale individuals look like they have the whole body covered by snow; treated as a noun in apposition. Remarks. ROM 92440 is not being considered in the type material as it is a dried specimen that disintegrated into several pieces. Zawadzki & Chamon (2013), in their list of Hypostominae of the rio Madeira, illustrated Panaque sp. 1 in page 312, and cited the lot UFRO-I 6384 as Panaque sp. 2, in page 315. In fact, there was a mistake in assigning the lots to the images. The illustration of Panaque sp. 1 shows in fact a specimen of Panaqolus nix and the correct number of this lot is UFRO-I 6384. The second illustration, Panaque sp. 2, is a different species and the correct numbers of the lots for this species are UFRO-I 6383 and UFRO-I 13109. So, Panaqolus nix was already known, but not named, as part of the ichthyofauna of the rio Madeira. Conservation status. The species seems to be widely distributed along rio Madeira, Mamoré and Tambopata as well. Despite the fact that part of its distribution includes two hydroelectric power dams, Jirau and Santo Antônio, the area of occurrence of Panaqolus nix goes well beyond the dams. Thus, considering that important threats to the species were not detected yet, P. nix should be classified as Least Concern (LC) according to the International Union for Conservation of Nature (IUCN) categories and criteria (IUCN Standards and Petitions Subcommittee, 2014). In the last years parts of the known habitats have been severely altered by the construction of these hydroelectric power plants, destroying the former Santo Antônio and Jirau rapids and transforming more than 200 km of the rio Madeira, enlarging the riverbed and reducing the current. Additional collecting efforts should be conducted in that region in order to better understand the impacts of these constructions on the population of Panaqolus nix and to be able to adjust (if necessary) the evaluation of the conservation status of the species.Published as part of Cramer, Christian Andreas & Py-Daniel, Lúcia Helena Rapp, 2015, A new species of Panaqolus (Siluriformes: Loricariidae) from the rio Madeira basin with remarkable intraspecific color variation, pp. 461-470 in Neotropical Ichthyology (Neotrop. Ichthyol.) (Neotrop. Ichthyol.) 13 (3) on pages 462-468, DOI: 10.1590/1982-0224-20140099, http://zenodo.org/record/455137
Supporting Data for “Why So Slow? Mechanistic Insights from Studies of a Poor Catalyst for Polymerization of ε-Caprolactone”
These files contain data along with associated output from instrumentation supporting all results reported in Stasiw, D. E.; Mandal, M.; Neisen, B. D.; Mitchell, L. A.; Cramer, C. J.; Tolman, W. B. Why so slow? Mechanistic insights from studies of a poor catalyst for polymerization of ε-caprolactone. Inorg. Chem., 2016, 56, 725–728. Polymerization of ε-caprolactone (CL) using an aluminum alkoxide catalyst (1) designed to prevent unproductive trans binding was monitored at 110 °C in toluene-d8 by 1H NMR and the concentration versus time data fit to a first-order rate expression. A comparison of t1/2 for 1 to values for many other aluminum alkyl and alkoxide complexes shows much lower activity of 1 toward polymerization of CL. Density functional theory calculations were used to understand the basis for the slow kinetics. The optimized geometry of the ligand framework of 1 was found indeed to make CL trans binding difficult: no trans-bound intermediate could be identified as a local minimum. Nor were local minima for cis-bound precomplexes found, suggesting a concerted coordination–insertion for polymer initiation and propagation. The sluggish performance of 1 is attributed to a high-framework distortion energy required to deform the “resting” ligand geometry to that providing optimal catalysis in the corresponding transition-state structure geometry, thus suggesting a need to incorporate ligand flexibility in the design of efficient polymerization catalysts..
Corresponding author for experimental data is William B. Tolman ([email protected]).
Corresponding author for computational data is Christopher J. Cramer ([email protected]).Funding for this project was provided by the Center for Sustainable Polymers at the University of Minnesota, a National Science Foundation (NSF)-supported Center for Chemical Innovation (Grant CHE-1413862). The X-ray diffraction experiments were performed using a crystal diffractometer acquired through NSF-MRI Award CHE-1229400. The authors acknowledge the MSI at the University of Minnesota for providing resources that contributed to the research results.Tolman, William, B; Cramer, Christopher, J; Stasiw, Daniel E; Mandal, Mukunda; Neisen, Benjamin D; Mitchell, Lauren A. (2017). Supporting Data for “Why So Slow? Mechanistic Insights from Studies of a Poor Catalyst for Polymerization of ε-Caprolactone”. Retrieved from the University Digital Conservancy, https://doi.org/10.13020/D6F60H
Dr. Arthur Pindle, Spelman College, April, 2012
This video is a conversation with Dr. Arthur Pindle. Dr. Pindle talks about his book, "Bayou St. John". Daniel Le, AUC Woodruff Library, is the interviewer
Dr. Duane M. Jackson, Morehouse College, July 2011
This video is a conversation with Dr. Duane M. Jackson. Dr. Jackson talks about his paper, "Recall and the Serial Position Effect: The Role of Primacy and Recency on Accounting Students' Performance." Jackie Daniel, AUC Woodruff Library, is the interviewer
Mr. Melvin J. Collier, RWWL AUC, June 2011
This video is a conversation with Mr. Melvin J. Collier. Mr. Collier talks about his book, "From Mississippi to Africa: A Journey of Discovery". Daniel Le, AUC Woodruff Library, is the interviewer
Dr. James Gillam, Spelman College, September 2011
This video is a conversation with Dr. James Gillam. Dr. Gillam talks about his book, "Life and Death in the Central Highlands: An American Sergeant in the Vietnam War 1968-1970". Daniel Le, AUC Woodruff Library, is the interviewer
Dr. Shanesha R.F. Brooks-Tatum, RWWL AUC, July 2011
This video is a conversation with Dr. Shanesha R.F. Brooks-Tatum. Dr. Brooks-Tatum talks about her book, "The Encyclopedia of Hip Hop Literature." Daniel Le, AUC Woodruff Library, is the interviewer
Poezja w protestanckich kancjonałach Białorusi w XVI wieku
Pierwsze poetyckie utwory renesansowe w języku starobiałoruskim i w łacinie zostały wydru kowane na początku XVI w. w Krakowie, Brześciu i Nieświeżu, zaś w latach 50.-60. XVI w. ukazywały się drukiem pierwsze wiersze i poematy w języku polskim. Aktywni działacze ruchu protestanckiego, usiłując spopularyzować w społeczeństwie nowe poglądy religijne, korzystali z dostępnej dla odbiorcy formy wiersza. W danym artykule autor zwraca szczególną uwagę na dwa kancjonały: brzeski Pieśni chwał Boskich, przygotowany przez Jana Zarębę i wydrukowany przez Stanisława Murmeliusa w 1558 r., oraz nieświeski Katechizm, albo krótkie w jedno miejsce zebra nie wiary i powinności Krześcijańskiej..., wydany w 1563 r. przez Daniela Łęczyckiego w drukami należącej do Macieja Kawiaczyńskiego. Zdaniem autora, wiersze zawarte w kancjonałach, będąc religijnymi utworami o charakterze publicystycznym, przygotowywały grunt do powstania świec kiej poezji politycznej.The first Renaissance poems in Old Belarussian and Latin were printed at the beginning of the 16lh century in Cracow, Brześć and Nieśwież, however the first poems in Polish came out in print in the 50s and 60s of the 16th century. Protestant activists of the Protestant movement poem, accessible to the reader, in order to popularize their religious views in the society. In the article the author places particular emphasis on two religious songbooks: the Brześć Pieśni chwał, by Jan Zaręba and printed by Stanislaw Murmelius in 1558, and the Nieśwież Katechizm, albo krótkie, w jedno miejsce zebranie wiary i powinności Krześcijańskiej, published in 1563 by Daniel Łęczy ca in the printing house of Maciej Kawiaczyński. The author expresses the view that, as religious works of commentary nature, the poems from the songbooks set the stage for the appearance of secular political poetry
American Roulette: The Effect of Reminders of Death on Support for George W. Bush in the 2004 Presidential Election
An experiment was conducted to assess the effect of a subtle reminder of death on voting intentions for the 2004 U.S. presidential election. On the basis of terror management theory and previous research, we hypothesized that a mortality salience induction would increase support for President George W. Bush and decrease support for Senator John Kerry. In late September 2004, following a mortality salience or control induction, registered voters were asked which candidate they intended to vote for. In accord with predictions, Senator John Kerry received substantially more votes than George Bush in the control condition, but Bush was favored over Kerry following a reminder of death, suggesting that President Bush's re-election may have been facilitated by non conscious concerns about mortality in the aftermath of September 11, 2001.This is an electronic version of the article published in Analyses of Social Issues and Public Policy, 5(1):177-187, 2005 Dec.The definitive version is available at www3.interscience.wiley.co
- …
