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Przejdź do strony domowej biblioteki Pedagogiczna Biblioteka Wojewódzka im. Komisji Edukacji Narodowej w Lublinie Link otwiera się w nowym oknie Logo biblioteki Prolib Integro - strona głównaPedagogiczna Biblioteka Wojewódzka im. Komisji Edukacji Narodowej w Lublinie
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Wyświetlanie 1-10 z 38
Tytuł:
Silk-collagen-inspired copolymer: promising biomaterial produced by yeasts
Autorzy:
Włodarczyk-Biegun, M.
Werten, M.
Wolf de, F.
Beucken van den, J.
Leeuwenburgh, S.
Stuart, M. C.
Kamperman, M.
Tematy:
copolymers
biomaterials
polymers
Pokaż więcej
Wydawca:
Akademia Górniczo-Hutnicza im. Stanisława Staszica w Krakowie. Polskie Towarzystwo Biominerałów
Powiązania:
https://bibliotekanauki.pl/articles/285324.pdf  Link otwiera się w nowym oknie
Dostawca treści:
Biblioteka Nauki
Artykuł
Tytuł:
Structure and evolution of the Carpathian thrust front between Tarnów and Pilzno (Pogórska Wola area, southern Poland) : results of integrated analysis of seismic and well data
Autorzy:
Krzywiec, P.
Oszczypko, N.
Bukowski, K.
Oszczypko-Clowes, M.
Śmigielski, M.
Stuart, F. M.
Persano, C.
Sinclair, H. D.
Tematy:
Carpathians
Carpathian Foredeep Basin
Pilzno embayment
Miocene
evaporites
wedge tectonics
Pokaż więcej
Wydawca:
Państwowy Instytut Geologiczny – Państwowy Instytut Badawczy
Powiązania:
https://bibliotekanauki.pl/articles/2060048.pdf  Link otwiera się w nowym oknie
Opis:
Seismic data and core from the shallow cartographic Pilzno P-7 borehole were used to construct a new model of the Carpathian orogenic front between Tarnów and Pilzno, in the Pogórska Wola area (southern Poland). The most external, frontal thrust of the orogenic wedge (the Jaśniny structure) was identified as a syn-depositional fault-propagation fold de- tached above the Upper Badenian evaporites. Its formation was controlled by the presence of mechanically weak foredeep evaporites and by the morphology of the sub-Miocene Meso-Paleozoic foreland plate (Jaśniny and Pogórska Wola palaeovalleys). The frontal zone of the Carpathian orogenic wedge (the Skole thrust sheet and the deformed foredeep deposits of the Zgłobice thrust sheet) is characterized by significant backthrusting of the foredeep succession towards the south, and by the presence of a triangle zone, with strongly deformed Upper Badenian evaporites of the Wieliczka Formation in its core. The triangle zone was formed during the latest thrusting movements of the Carpathians. An indication of the existence of the triangle zone in the vicinity of Dębica has also been provided by reinterpretation of the archive regional geological cross-section. The youngest foredeep deposits, brought to the surface above the backthrust, have been dated as Sarmatian (NN7 nannoplankton zone), which indicates that the latest thrust movements within the frontal Carpathian orogenic in the vicinity of Tarnów-Dębica took place approx. 11-10 million years ago. Thermochronological studies (AFT and AHe) indicated that the foredeep succession drilled by the Pilzno P-7 borehole has not been buried deeper than 1.5-2 km, which is compatible with reconstruction based on the seismic data.
Dostawca treści:
Biblioteka Nauki
Artykuł
Tytuł:
Contribution of insect pollinators to crop yield and quality varies with agricultural intensification
Autorzy:
Krewenka, Kristin M.
Szentgyörgyi, Hajnalka
Steffan-Dewenter, Ingolf
Bommarco, Riccardo
Tscheulin, Thomas
Westphal, Catrin
Potts, Simon G.
Vaissiere, Bernard E.
Roberts, Stuart P. M.
Woyciechowski, Michał
Bartomeus, Ignasi
Opis:
Background. Up to 75% of crop species benefit at least to some degree from animal pollination for fruit or seed set and yield. However, basic information on the level of pollinator dependence and pollinator contribution to yield is lacking for many crops. Even less is known about how insect pollination affects crop quality. Given that habitat loss and agricultural intensification are known to decrease pollinator richness and abundance, there is a need to assess the consequences for different components of crop production. Methods. We used pollination exclusion on flowers or inflorescences on a whole plant basis to assess the contribution of insect pollination to crop yield and quality in four flowering crops (spring oilseed rape, field bean, strawberry, and buckwheat) located in four regions of Europe. For each crop, we recorded abundance and species richness of flower visiting insects in ten fields located along a gradient from simple to heterogeneous landscapes. Results. Insect pollination enhanced average crop yield between 18 and 71% depending on the crop. Yield quality was also enhanced in most crops. For instance, oilseed rape had higher oil and lower chlorophyll contents when adequately pollinated, the proportion of empty seeds decreased in buckwheat, and strawberries’ commercial grade improved; however, we did not find higher nitrogen content in open pollinated field beans. Complex landscapes had a higher overall species richness of wild pollinators across crops, but visitation rates were only higher in complex landscapes for some crops. On the contrary, the overall yield was consistently enhanced by higher visitation rates, but not by higher pollinator richness. Discussion. For the four crops in this study, there is clear benefit delivered by pollinators on yield quantity and/or quality, but it is not maximized under current agricultural intensification. Honeybees, the most abundant pollinator, might partially compensate the loss of wild pollinators in some areas, but our results suggest the need of landscape-scale actions to enhance wild pollinator populations.
Dostawca treści:
Repozytorium Uniwersytetu Jagiellońskiego
Artykuł
Autorzy:
Solans, C.
Andre, K. D. J.
Spiesberger, H.
Cakir, O.
Denizli, H.
Cruz-Alaniz, E.
Ruan, X.
Camarda, S.
Olivier, G.
Luo, X.
Azuelos, G.
Lei, G.
Lappi, T.
Glover, N.
Zhang, J.
Flores-Sánchez, O.
Krelina, M.
Gonzalez-Sprinberg, G. A.
Nowakowski, M.
Yock, P.
Hessler, J.
Xiaohao, C.
Bertolucci, S.
Coleppa, B.
Jana, S.
Tudora, A.
Alekhin, S.
Yamaguchi, Y.
Turk Cakir, I.
Raicevic, N.
Pan, R.
Morreale, A.
Sinha, N.
Shipman, N.
Olry, G.
Tommasini, D.
Perez-Segurana, G.
Giuli, F.
Gehrmann-De Ridder, A.
Sahin, M.
Harland-Lang, L.
Jansova, M.
Godbole, R. M.
Lobodzinska, E.
Zomer, F.
Behnke, O.
Salgado, C. A.
Pietralla, N.
Granados, E.
Hayden, D.
Apsimon, R.
Khalek, R. A.
Martens, A.
Calıskan, A.
Li, X.
Wei, H.
Korostelev, M.
Kaabi, W.
Laycock, P.
Han, C. C.
Hesari, H.
Stanyard, J.
Rosado, A.
Smith, S.
Russenschuck, S.
Gunaydin, Y. O.
Mitra, M.
Daly, E.
Angal-Kalinin, D.
Trbojevic, D.
Mäntysaari, H.
Kretzschmar, J.
Liuti, S.
Newman, P.
Ratoff, P.
Moretti, S.
Catalan-Lasheras, N. C.
Corsini, R.
Poelker, M.
Litvinenko, V.
Wang, B.
Pires, J.
Paukkunen, H.
Zhang, R.
Armbruster, A.
Gilbert, A.
de Blas, J.
Sekine, T.
Liu, Y.
Sampayo, O. A.
Zhang, Z.
Wollmann, D.
Pire, B.
Nissen, E. A.
Kulipanov, G.
Wang, K.
Karadeniz, H.
Das, A.
Rezaeian, A. H.
Cooper-Sarkar, A.
Gehrmann, T.
Bailey, I.
Tsurin, I.
Kalinin, D. A.
Duarte, L.
Cormier, E.
Valloni, A.
Tanaka, M.
Bordry, F.
Auchmann, B.
Wallon, S.
Schenke, B.
Nergiz, Z.
Brüning, O.
Gerigk, F.
Słomiński, Wojciech
Tywoniuk, K.
Dutta, S.
Mohammadi Najafabadi, M.
Bogacz, A.
Huss, A.
Senol, A.
Nadolsky, P.
Köksal, M.
Osborne, J. A.
Rashed, A.
Aperio Bella, L.
Mondal, S.
Tapia-Takaki, D.
Bracinik, J.
Apolinario, L.
Latina, A.
Cassou, K.
Militsyn, B.
Yue, C. X.
Olness, F.
Zurita, P.
Queiroz, F. S.
Haug, F.
Cepila, J.
Repond, J.
Cetinkaya, V.
Raut, D.
Yang, H.
Honorato, C. G.
Kocak, F.
Hoffstaetter, G. H.
Stasto, A.
Eichhorn, R.
Trott, M.
Shang, L.
Peinaud, Y.
Klein, U.
Deshpande, K. S.
Satendra, K.
Marhauser, F.
Liu, M.
Eskola, K. J.
Schulte, D.
Patra, M.
Liang, H.
Balli, F.
Bruni, C.
Hug, F.
Dassa, L.
Kostka, P.
Holzer, B.
Levitchev, E.
Apyan, A.
Starostenko, A.
Gonçalves, V.
Hod, N.
Dainton, J.
Kado, M.
Li, R.
Strikman, M.
Brodsky, S. J.
Goddard, B.
Liu, T.
Satyanarayan, N.
Wang, X.
Gaddi, A.
Perrot, L.
Hutton, A.
Kumar, M.
Fischer, O.
Zhang, C.
Pellegrini, D.
Rahaman, R.
Szymanowski, L.
Marquet, C.
Currie, J.
Sutton, M.
Bousson, S.
Milhano, J. G.
Tasci, A. T.
Kawaguchi, S.
McFayden, J.
Hounsell, B.
Hernandez-Sanchez, J.
Allport, P. P.
Backovic, S.
Okada, N.
Tomas-Garcia, R.
Welsch, C.
Willering, G.
Britzger, D.
Agostini, P.
Tapan, I.
Verney, D.
Grassellino, A.
Aulenbacher, K.
Niehues, J.
Bernauer, J.
Pownall, G.
Yilmaz, A.
Ma, W.
Efremov, A. V.
Schwanenberger, C.
Biswal, S. S.
Rai, S. K.
Williams, P. H.
Ozansoy, A.
Grames, J.
Setiniyaz, S.
Jensen, E.
Rabbertz, K.
Delle Rose, L.
Bouzas, A. O.
Andari, N.
Burkhardt, H.
Larios, F.
Benedikt, M.
Das, S. P.
Ben-Zvi, I.
Longuevergne, D.
Levy, A.
Caldwell, A.
Parker, B.
Meot, F.
Stuart, M. J.
Zadeh, S. G.
Goyal, A.
Helenius, I.
Raychaudhuri, S.
Machado, M.
Milanese, A.
Mandal, S.
Polini, A.
Gao, J.
Islam, R.
Zimmermann, F.
Chetvertkova, V.
Yamazaki, Y.
Rinolfi, L.
Blümlein, J.
Polifka, R.
Armesto, N.
Dupraz, K.
Sultansoy, S.
Cornell, A. S.
Wang, Z. S.
Boonekamp, M.
Kaya, U.
Moch, S.
Kilic, A.
Marzani, S.
Aksakal, H.
Schirm, K.
Mcintosh, P.
Perini, D.
D’Onofrio, M.
Rimmer, R.
Boroun, G. R.
Radescu, V.
Martin, R.
Guzey, V.
Thonet, P.
Navarra, F.
Stocchi, A.
Bracco, C.
Henry, J.
Schopper, H.
Bottura, L.
Ari, V.
Shen, X.
Levonian, S.
Sun, H.
Douglas, D.
Ten-Kate, A. T.
Tang, Y.
Zhu, G.
Zurita, J.
Cole, B.
Poulose, P.
Ferreiro, E. G.
Hu, N.
Forte, S.
Xu, T.
Klein, M.
Guo, Y. C.
Seryi, A.
Vallerand, C.
Bonvini, M.
Kluth, S.
Morgan, T.
Zhu, S.
Glazov, A.
Zenaiev, O.
Pupkov, Y. A.
Gwenlan, C.
Calaga, R.
Kuze, M.
Placakyte, R.
Pilicer, E.
Bailey, S.
Hammad, A.
Hautmann, F.
Arduini, G.
Liu, W.
Walker, D.
Jones, T.
Song, M.
Kuday, S.
Hobbs, T. J.
Rojo, J.
Curtin, D.
Antusch, S.
Mellado, B.
Yaguna, C. E.
Khanpour, H.
Schott, M.
Behera, S.
Vilella, E.
Iwamoto, S.
Jowett, J. M.
Opis:
The Large Hadron–Electron Collider (LHeC) is designed to move the field of deep inelastic scattering (DIS) to the energy and intensity frontier of particle physics. Exploiting energy-recovery technology, it collides a novel, intense electron beam with a proton or ion beam from the High-Luminosity Large Hadron Collider (HL-LHC). The accelerator and interaction region are designed for concurrent electron–proton and proton–proton operations. This report represents an update to the LHeC’s conceptual design report (CDR), published in 2012. It comprises new results on the parton structure of the proton and heavier nuclei, QCD dynamics, and electroweak and top-quark physics. It is shown how the LHeC will open a new chapter of nuclear particle physics by extending the accessible kinematic range of lepton–nucleus scattering by several orders of magnitude. Due to its enhanced luminosity and large energy and the cleanliness of the final hadronic states, the LHeC has a strong Higgs physics programme and its own discovery potential for new physics. Building on the 2012 CDR, this report contains a detailed updated design for the energy-recovery electron linac (ERL), including a new lattice, magnet and superconducting radio-frequency technology, and further components. Challenges of energy recovery are described, and the lower-energy, high-current, three-turn ERL facility, PERLE at Orsay, is presented, which uses the LHeC characteristics serving as a development facility for the design and operation of the LHeC. An updated detector design is presented corresponding to the acceptance, resolution, and calibration goals that arise from the Higgs and parton-density-function physics programmes. This paper also presents novel results for the Future Circular Collider in electron–hadron (FCC-eh) mode, which utilises the same ERL technology to further extend the reach of DIS to even higher centre-of-mass energies.
Dostawca treści:
Repozytorium Uniwersytetu Jagiellońskiego
Artykuł
Wyświetlanie 1-10 z 38

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