Portal de Periódicos da CAPES

L. Degiorgi, S. Teraoka, Giuseppe Compagnini, P. Wächter,

We report on our thorough optical investigations of the Yb pnictide compounds, performed over a large photon-energy spectral range. From Kramers-Kronig analysis we obtain the complete excitation spectrum in terms of the optical dielectric functions. Applying a phenomenological harmonic-oscillator model we extract the unscreened plasma frequency and the resonance frequency of the transverse-optical-phonon mode. Our experimental findings suggest furthermore a d-4f electronic transition at about 0. ...

Tópico(s): Physics of Superconductivity and Magnetism

1993 - American Physical Society | Physical review. B, Condensed matter

Dietmar Kuck,

... L. M., J. Am. Chem. Soc. 1974, 96, 5715–5722. 187 Vincow, G.; Dauben, H. J., Jr.; ...

Tópico(s): Mass Spectrometry Techniques and Applications

1990 - Wiley | Mass Spectrometry Reviews

R Gorlin, Valentı́n Fuster, John A. Ambrose,

... Diagnosis and Treatment, 10.1007/978-1-4615-5715-9_3, (87-100), . Spaulding C, Joly L, ... 1989. Lo Y, Abi-Mansour P, Kaplan K, Kramer B, Hill I, Meyers S and Lesch M ( ...

Tópico(s): Cardiac electrophysiology and arrhythmias

1986 - Lippincott Williams & Wilkins | Circulation

Eugene Kim, Edward J. Krämer, Wan C. Wu, Paul Garrett,

Forward recoil spectrometry was used to obtain the tracer (D*) and mutual (D̃) diffusion coefficients in a miscible polymer blend of poly(methyl methacrylate) (PMMA, Tg=136°C) and poly(styrene-co-acrylonitrile) with ∼23 wt% acrylonitrile content (SAN, Tg=112°C). For blends with SAN weight fraction w of 0.2 and 0.5, the temperature dependence of D* for both species was nearly identical. Tracer diffusion coefficients D*PMMA and D*SAN were determined for matrices consisting of 176 000 molecular weight SAN ( ...

Tópico(s): Asphalt Pavement Performance Evaluation

1994 - Elsevier BV | Polymer

Edward H. Schuster, Bernadine H. Bulkley,

... Diagnosis and Treatment, 10.1007/978-1-4615-5715-9_5, (143-197), . Popović A (1998) Echocardiographic ...

Tópico(s): Cardiac Fibrosis and Remodeling

1979 - Lippincott Williams & Wilkins | Circulation

B. Abelev, J. Adam, D. Adamová, A. Adare, M. M. Aggarwal, G. Aglieri Rinella, M. Agnello, A.G. Agócs, A. Agostinelli, Z. Ahammed, N. Ahmad, A. Ahmad Masoodi, S. U. Ahn, Sul-Ah Ahn, M. Ajaz, A. Akindinov, D. Aleksandrov, B. Alessandro, A. Alici, A. Alkin, E. Almaráz Aviña, J. Alme, T. Alt, V. Altini, S. Altinpinar, I. Altsybeev, C. Andrei, A. Andronic, V. Anguelov, J. Anielski, C. Anson, T. Antičić, F. Antinori, P. Antonioli, L. Aphecetche, H. Appelshäuser, N. Arbor, S. Arcelli, A. Arend, N. Armesto, R. Arnaldi, T. Aronsson, I. C. Arsene, M. Arslandok, A. Asryan, A. Augustinus, R. Averbeck, T. C. Awes, J. Äystö, M. D. Azmi, M. Bach, A. Badalà, Y. W. Baek, R. Bailhache, R. Bala, A. Baldisseri, F. Baltasar Dos Santos Pedrosa, J. Bán, R. C. Baral, R. Barbera, F. Barile, G. G. Barnaföldi, L. S. Barnby, V. Barret, J. Bartke, M. Basile, N. Bastid, S. Basu, B. Bathen, G. Batigne, B. Batyunya, C. Baumann, I. G. Bearden, H. Beck, N. K. Behera, I. Belikov, F. Bellini, R. Bellwied, E. Belmont‐Moreno, G. Bencédi, S. Beolè, I. Berceanu, A. Bercuci, Y. Berdnikov, D. Berényi, A. A. E. Bergognon, D. Berzano, L. Betev, A. Bhasin, A. K. Bhati, J. Bhom, L. Bianchi, N. Bianchi, J. Bielčík, J. Bielčíková, A. Bilandzic, S. Bjelogrlic, F. Blanco, F. Blanco, D. Blau, C. Blume, M. Boccioli, S. Böttger, A. Bogdanov, H. Bøggild, M. Bogolyubsky, L. Boldizsár, M. Bombara, J. Book, H. Borel, A. Borissov, F. Bossú, M. Botje, E. Botta, E. Braidot, P. Braun‐Munzinger, M. Bregant, T. Breitner, T. A. Broker, T. A. Browning, M. Broz, R. Brun, E. Bruna, G. Bruno, D. Budnikov, H. Buesching, S. Bufalino, P. Bunčić, O. Busch, Z. Buthelezi, D. Caballero Orduna, D. Caffarri, X. Cai, X. Z. Cai, E. Calvo Villar, P. Camerini, V. Canoa Roman, G. Cara Romeo, F. Carena, W. Carena, N. Carlin Filho, F. Carminati, A. Casanova Díaz, J. Castillo Castellanos, J. F. Castillo Hernandez, Ester Anna Rita Casula, V. Catanescu, C. Cavicchioli, C. Ceballos Sánchez, J. Cepila, P. Cerello, B. Chang, S. Chapeland, J. L. Charvet, S. Chattopadhyay, S. Chattopadhyay, M. Cherney, C. Cheshkov, B. Cheynis, V. Chibante Barroso, D. D. Chinellato, P. Chochula, M. Chojnacki, S. Choudhury, P. Christakoglou, C. H. Christensen, P. Christiansen, T. Chujo, S. U. Chung, C. Cicalò, L. Cifarelli, F. Cindolo, J. Cleymans, F. Colamaria, D. Colella, A. Collu, G. Conesa Balbastre, Z. Conesa del Valle, M. Connors, G. Contin, J. G. Contreras, T. M. Cormier, Y. Corrales Morales, P. Cortese, I. Cortés Maldonado, M. R. Cosentino, F. Costa, M. E. Cotallo, E. Crescio, P. Crochet, E. Cruz Alaniz, R. Cruz Albino, E. Cuautle, L. Cunqueiro, A. Dainese, A. Danu, D. Das, I. Das, S. Das, K. Das, S. Dash, A. Dash, S. De, G. O. V. de Barros, A. De, G. de Cataldo, J. de Cuveland, D. De Gruttola, D. De Gruttola, H. Delagrange, A. Deloff, N. De Marco, E. Dénes, S. De Pasquale, A. Deppman, G. D Erasmo, R. de Rooij, M. A. Diaz Corchero, D. Di Bari, T. Dietel, C. Di Giglio, S. Di Liberto, B. Di Ruzza, P. Di Nezza, R. Divià, Ø. Djuvsland, A. Dobrin, T. Dobrowolski, B. Dönigus, O. Dordic, O. Driga, A. K. Dubey, A. Dubla, L. Ducroux, P. Dupieux, A. K. Dutta Majumdar, D. Elia, D. Emschermann, H. Engel, B. Erazmus, H. A. Erdal, B. Espagnon, M. Estienne, S. Esumi, D. Evans, G. Eyyubova, D. Fabris, J. Faivre, D. Falchieri, A. Fantoni, M. Fasel, R. W. Fearick, D. Fehlker, L. Feldkamp, D. Felea, A. Feliciello, B. Fenton-Olsen, Г. Феофилов, A. Fernández Téllez, A. Ferretti, A. Festanti, J. Figiel, M. A. S. Figueredo, S. Filchagin, D. Finogeev, F. M. Fionda, E. M. Fiore, E. Floratos, M. Floris, S. Foertsch, P. Foka, S. Fokin, E. Fragiacomo, A. Francescon, U. Frankenfeld, U. Fuchs, C. Furget, M. Fusco Girard, J. J. Gaardhøje, M. Gagliardi, A. M. Gago, M. Gallio, D. R. Gangadharan, P. Ganoti, C. Garabatos, E. García-Solis, C. Gargiulo, I. Garishvili, J. Gerhard, M. Germain, C. Geuna, A. Gheata, M. Gheata, B. Ghidini, P. Ghosh, P. Gianotti,

This publication describes the methods used to measure the centrality of inelastic Pb-Pb collisions at a center-of-mass energy of 2.76 TeV per colliding nucleon pair with ALICE. The centrality is a key parameter in the study of the properties of QCD matter at extreme temperature and energy density, because it is directly related to the initial overlap region of the colliding nuclei. Geometrical properties of the collision, such as the number of participating nucleons and the number of binary nucleon- ...

American Institute of Physics