Autor: Jacak, W. - Prolib Integro

Skocz do pozycji: 1.

Tytuł:: Size effect in plasmon resonance of metallic nanoparticles: RPA versus COMSOL
Autorzy:: Kluczyk, K.
Jacak, W.
Tematy:: 36.40.Gk
73.20.Mf; Pokaż więcej
Wydawca:: Polska Akademia Nauk. Instytut Fizyki PAN
Powiązania:: https://bibliotekanauki.pl/articles/1075371.pdf Link otwiera się w nowym oknie
Opis:: Size effect for plasmon resonance in metallic nanoparticles has been studied by finite element method solution of the Maxwell equations (COMSOL), by the Mie approach and microscopic random phase approximation model. Comparison with Au, Ag nanoparticles experimental data for light extinction in colloidal solutions with different particle sizes is presented for the three types of approach.
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 2.

Tytuł:: Absorption Enhancement in Si Solar Cells by Incorporation of Metallic Nanoparticles: Improved COMSOL Numerical Study Including Quantum Corrections
Autorzy:: Kluczyk, K.
Krzemińska, Z.
Jacak, W.
Tematy:: solar cells
solar energy harvesting
surface plasmons
metallic nanoparticles; Pokaż więcej
Wydawca:: Polska Akademia Nauk. Instytut Fizyki PAN
Powiązania:: https://bibliotekanauki.pl/articles/1033865.pdf Link otwiera się w nowym oknie
Opis:: One of the crucial parameters affecting the solar cell efficiency is the absorption rate versus solar spectrum. Metallic nanoparticles deposited on the cell surface can mediate this process. Main mechanisms of absorption enhancement due to metallic nanoparticle plasmons were proposed: (1) the scattering of incident solar light causing increase of the optical path length inside active layer and local enhancement of the electric field; (2) near field coupling between plasmon and semiconductor and the direct generation of electron-hole pairs in the semiconductor. The field concentration effect can be described by classical electrodynamic theory, the coupling between metallic nanoparticle plasmons and band electrons in semiconductor substrate must be captured upon quantum mechanics. In this paper we took the challenge to develop fast and reliable method for calculation of device optical properties by application of COMSOL system appropriately configured to take into account these quantum effects, via the quantum modification of the dielectric function of semiconductor substrate and metallic components. The presented results indicate that the efficiency of energy transfer due to near field coupling of metallic nanoparticle plasmons with semiconductor substrate is much more effective than the absorption increase due to metallic nanoparticle plasmons scattering only.
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 3.

Tytuł:: Model of Qubit in Multi-Electron Quantum Dot
Autorzy:: Jacak, L.
Krasnyj, J.
Jacak, D.
Salejda, W.
Mituś, A.
Tematy:: 73.20.Dx; Pokaż więcej
Wydawca:: Polska Akademia Nauk. Instytut Fizyki PAN
Powiązania:: https://bibliotekanauki.pl/articles/2024044.pdf Link otwiera się w nowym oknie
Opis:: The discussion of qubit for quantum computation in quantum dots technology is presented. The state-of-the-art structure of multi-electron dot is considered and the appropriate quasi-two-level system is suggested employing the singlet-triplet transition in the presence of magnetic field. The methods of qubit rotation (the write procedure) as well as two-qubit operations, as controlled-NOT, in vertically stacked dots system are analysed.
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 4.

Autorzy:: Pire, B.
Tripathi, S.
Antonioli, P.
Flore, C.
Hauenstein, F.
Moiseev, V.
Stewart, I.W.
Jezo, T.
Li, S.
Bozzi, G.
Santopinto, E.
Bacchetta, A.
Higinbotham, D.W.
Širca, S.
Dasgupta, S.S.
Noferini, F.
Bissolotti, C.
Soto, O.
Gay Ducati, M.B.
Wei, S.Y.
Xie, J.
El Fassi, L.
Moutarde, H.
Evdokimov, O.
Fernandez-Ramirez, C.
Baker, M.D.
Pasquini, B.
Terry, J.
Zhang, J.
Bufalino, S.
Tezgin, K.
Seidl, R.
Collins, J.L.
Liu, X.
Gao, H.
Krelina, M.
Fanelli, C.
Paukkunen, H.
Van Hulse, C.
Kalantarians, N.
Stutzman, M.L.
Battaglieri, M.
Wallon, S.
Zheng, L.
Lappi, T.
Kumar, K.S.
Goncalves, V.P.
Klasen, M.
Hohlmann, M.
Cisbani, E.
Olness, F.
Poblaguev, A.A.
Ringer, F.
Mkrtchyan, H.
Mondal, M.M.
Mehtar-Tani, Y.
Surrow, B.
Sato, N.
Chudakov, E.
Dumitru, A.
Tu, Z.
Gonella, L.
Ullrich, T.
Kalicy, G.
Morreale, A.
Woody, C.
Lunghi, E.
Mkrtchyan, A.
Sherrill, N.
Kumar, L.
Tuvè, C.
Dalla Torre, S.
Keppel, C.E.
Hen, O.
Kiselev, A.
Cosyn, W.
Durham, J.M.
Contin, G.
Preghenella, R.
Kim, J.
Schweitzer, P.
Chatterjee, C.
Pegg, I.L.
Brei, N.
Kutak, K.
Torales Acosta, F.
Furletov, S.
Dilks, C.
Wang, X.
Celentano, A.
Romanov, D.
Ethier, J.J.
Schnell, G.
Detmold, W.
Brooks, W.K.
Kotko, P.
Liyanage, N.
Bhattacharya, S.
Barion, L.
Fitzgerald, D.
Petti, R.
Schenke, B.
Janoska, Z.
Murray, M.J.
Purschke, M.L.
Bazilevsky, A.
Jadhav, M.
Pecar, C.
Colella, D.
Fazio, S.
Rossi, P.
Abdul Khalek, R.
Posik, M.
Song, Y.
Boglione, M.
Zhang, Z.
Singh, B.K.
Chen, K.
Wikramanayake, A.
Da Silva, C.
Lee, K.
Reimer, P.E.
Brandenburg, J.D.
Mantry, S.
Lai, Y.S.
Glazier, D.I.
Adamiak, D.
Delcarro, F.
Schmookler, B.
Eyser, K.O.
Pitonyak, D.
Peng, C.
Nam, J.
Valentini, A.
Liuti, S.
Gonzalez Hernandez, J.O.
Bukhari, M.H.S.
Musico, P.
Sterman, G.
Sichtermann, E.
Volpe, G.
Kuleshov, S.
Potekhin, M.
Muñoz Camacho, C.
Scopetta, S.
Rinaldi, M.
Greiner, L.C.
Hyde, C.E.
Liu, H.
Wang, Q.
Lukow, N.S.
Sassot, R.
Slifer, K.
Hiller Blin, A.N.
Kang, Z.B.
Dehmelt, K.
Szymanowski, L.
Vitev, I.
Słomiński, Wojciech
Kauder, K.
Petriello, F.
Cicala, G.
Zurita, P.
Mäntysaari, H.
Mirazita, M.
Chien, Y.-T.
Xu, Q.H.
Rajput-Ghoshal, R.
Gericke, M.
Kay, S.J.D.
Mastroserio, A.
Crafts, J.
Aune, S.
Kostina, A.
Xiao, B.W.
Behera, N.K.
Joosten, S.
Signori, A.
Stepanov, P.
Celiberto, F.G.
Pilloni, A.
Lawrence, D.
Klest, H.T.
Tassielli, G.F.
Borsa, I.
Mendez, L.
Xing, H.
Finger, M.
Lu, Z.
Gil Da Silveira, G.
Voutier, E.
Osborn, J.D.
Sekula, S.
Li, H.
Bossù, F.
Nguyen, D.
Weiss, C.
Vossen, A.
Jacak, B.V.
Guzey, V.
Cuevas, R.C.
Lalwani, K.
Pinkenburg, C.
Camsonne, A.
Al-bataineh, A.
Mandjavidze, I.
Akers, W.
Li, W.
Gnanvo, K.
Dixit, D.U.
Frederico, T.
Echevarria, M.G.
Bondì, M.
Cocuzza, C.
Lucero, G.
Rojo, J.
Chiarusi, T.
Sznajder, P.
Prokudin, A.
Dulat, S.
Klein, S.
Wenaus, T.
Constantinou, M.
Ameli, F.
Vladimirov, A.
Cloet, I.C.
Okorokov, V.A.
Stevens, J.R.
Page, B.S.
Schmidke, W.B.
Barish, K.N.
Radici, M.
Szczepaniak, A.
Hattawy, M.
Hemmick, T.K.
Strikman, M.
Esha, R.
Tsai, O.D.
Gaskell, D.
Chang, W.
Cruz-Torres, R.
Defurne, M.
Del Dotto, A.
Horn, T.
Tribedy, P.
Mochalov, V.
Tapia Takaki, J.D.
Tadepalli, A.S.
Rodini, S.
Mihovilovič, M.
Li, X.
Asai, M.
Perrino, R.
Korchak, O.
Melnitchouk, W.
Schmidt, A.
Ayerbe Gayoso, C.
Metz, A.
Liu, M.X.
Azmoun, B.
Murgia, F.
Jacobs, P.M.
Armesto, N.
Boer, D.
Deconinck, W.
Lee, C.
He, X.
Kovchegov, Y.V.
Parker, A.
Albaladejo, M.
Makris, Y.
Spiesberger, H.
Segovia, J.
Huang, Q.
Lavinsky, M.
Nocera, E.R.
Nunes, A.S.
Meziani, Z.-E.
Roberts, C.D.
Contalbrigo, M.
Sarsour, M.
Paschke, K.
Mezrag, C.
Friščić, I.
Gates, K.
Majka, R.
Marhauser, F.
Sullivan, M.
Pujahari, P.
Chu, X.
Guryn, W.
Schwiening, J.
Buttimore, N.H.
Semenov-Tian-Shanskiy, K.
Ilieva, Y.
Pybus, J.R.
Girod, F.-X.
Triloki,
Winney, D.
Varner, G.
Avagyan, H.
Vancura, P.
Xia, L.
Zhao, Z.W.
Lauret, J.
Jentsch, A.
Joo, K.
Noto, F.
Gal, C.
Cole, P.L.
Adam, J.
Berdnikov, V.V.
Wickramaarachchi, N.
Courtoy, A.
Bertone, V.
Strakovsky, I.
Zhao, Y.X.
Furletova, Y.
Kumar, R.
Vandenbroucke, M.
Bernauer, J.C.
Heyes, G.
Szumila-Vance, H.
Pisano, C.
Kang, D.
Morrison, D.
Li, W.B.
Chiosso, M.
Ent, R.
Goto, Y.
Sturm, M.
Milner, R.
Tessarotto, F.
Barry, P.C.
Polakovic, T.
Arratia, M.
Hobbs, T.J.
Bressan, A.
Kumano, S.
Barbosa, F.
Gamberg, L.
Boora, P.
Scimemi, I.
Accardi, A.
Hou, T.-J.
Preins, S.
Wagner, J.
Asaturyan, A.
Marsicano, L.
Sondheim, W.E.
Neyret, D.
Wang, H.
Shao, D.Y.
Nadolsky, P.M.
Fatemi, R.
Trotta, R.L.
Nadel-Turonski, P.
Alexeev, M.G.
Lorcé, C.
Syritsyn, S.
Schmidt, I.
Pentchev, L.
Svihra, P.
Kumerički, K.
Venugopalan, R.
Jing, X.
Ungaro, M.
Wong, C.P.
Sokhan, D.
Tomasek, L.
Burkert, V.
Das, D.
Motyka, Leszek
Benmokhtar, F.
Markowitz, P.
Arrington, J.
Pellegrino, C.
Huang, J.
Deshpande, A.
Chetry, T.
Elia, D.
Aschenauer, E.C.
Levorato, S.
Huber, G.M.
Park, S.
Lednicky, D.
Paul, S.
De Vita, R.
Jones, P.G.
Hatta, Y.
Iakovidis, G.
DeGraw, W.
Corliss, R.
Garg, P.
Lee, S.H.
Tricoli, A.
Ligonzo, T.
Kafka, V.
Armstrong, W.R.
Siddikov, M.
Mathieu, V.
Kusina, A.
Grancagnolo, F.
Fucini, S.
Dupré, R.
Zhang, S.
Urciuoli, G.M.
D'Alesio, U.
Stasto, A.M.
Diefenthaler, M.
Newman, P.R.
Zhou, Y.
Wennlöf, H.
Dostawca treści:: Repozytorium Uniwersytetu Jagiellońskiego

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Skocz do pozycji: 5.

Tytuł:: Hot QCD white paper
Autorzy:: Perepelitsa, D. V.
O'Brien, E.
Zajc, W. A.
Niida, T.
Yee, H. -U.
Wang, F.
Ratti, C.
Shi, Z.
Bock, F.
Schäfer, T.
Narde, A.
Koch, V.
Finger Jr., M.
Putschke, J.
Berdnikov, Y.
Ramasubramanian, N. V.
Bossi, H.
Drees, A.
Salur, S.
Voloshin, S. A.
Ye, Z.
Schenke, B.
Lajoie, J. G.
Morrison, D. P.
Judd, E. G.
Yao, X.
Shen, C.
Hong, B.
Caines, H.
Jacak, B. V.
Praszałowicz, Michał
Kotov, D.
Odyniec, G.
Evdokimov, O.
Timmins, A. R.
Bautista, I.
Jheng, H. R.
Karpenko, I.
Song, H.
Knospe, A. G.
Jahan, J.
Blair, J. T.
Tribedy, P.
Yang, Y.
Luo, X.
Teaney, D.
Videbæk, F.
Durham, J. M.
Boimska, B.
Liu, M. X.
Khachatryan, V.
Dexheimer, V.
Lim, S. H.
Okorokov, V. A.
Schmidt, N. V.
Loizides, C.
Csanád, M.
Osborn, J. D.
Reed, R.
Kharzeev, D. E.
Thomas, D.
Ruan, L.
Jeon, S.
Majumder, A.
Seger, J.
Gonzalez, V.
Soudi, I.
Chen, Y.
Minafra, N.
Menon, A. S.
Xie, W.
Nagle, J. L.
Kimelman, B.
Dash, A. P.
Schmier, A.
Bielcik, J.
Becattini, F.
Rueda, O. V.
Stephanov, M.
Luzum, M.
Tapia Takaki, D.
Venugopalan, R.
Nouicer, R.
Royon, C.
Steinberg, P.
Hachiya, T.
Dehmelt, K.
Mueller, B.
Dong, X.
Ma, R.
Mehtar-Tani, Y.
Petreczky, P.
Greene, S. V.
Frawley, A. D.
Geurts, F.
Chien, Y. -T.
He, X.
Sumbera, M.
Klein, S. R.
Rosati, M.
Tu, Z.
Heinz, U.
Klay, J. L.
Strickland, M.
Weyhmiller, S.
Stahl Leiton, A. G.
Noronha-Hostler, J.
Krintiras, G. K.
Rinn, T.
Read, K. F.
Tang, A. H.
Mak, S.
Novitzky, N.
Gale, C.
Ivanishchev, D.
Ehlers, R. J.
Likmeta, I.
Mignerey, A. C.
Arslandok, M.
Noronha, J.
Sakaguchi, T.
Frantz, J.
Grau, N.
Singh, M.
Smith, K. L.
Sarsour, M.
Bellwied, R.
Seto, R
Smirnov, N.
Park, S.
Vovchenko, V.
Humanic, T. J.
Liao, J.
Elfner, H.
Sickles, A. M.
Singh, B. K.
Bass, S. A.
Beattie, C.
Kim, M.
Kuo, C. M.
Grossberndt, S. K.
Baty, A. A.
Wang, X. -N.
Kapusta, J. I.
Berdnikov, A.
Nattrass, C. E.
Vujanovic, G.
Shulga, E.
Velkovska, J.
Chiu, M.
Finger, M.
Sunar Cerci, D.
Connors, M. E.
Rebello Teles, P.
Jia, J.
Wang, X.
David, G.
Paquet, J. -F.
Rapp, R.
Tuo, S.
Du, L.
Kunnawalkam Elayavalli, R.
Lee, Y. -J.
Longo, R.
Xu, N.
Markert, C.
Pruneau, C.
Parotto, P.
Pinkenburg, C.
Sheibani, Oveis
Tachibana, Y.
da Silva, C. L.
Li, W.
Roland, G.
Opis:: Hot QCD physics studies the nuclear strong force under extreme temperature and densities. Experimentally these conditions are achieved via high-energy collisions of heavy ions at the Relativistic Heavy Ion Collider (RHIC) and the Large Hadron Collider (LHC). In the past decade, a unique and substantial suite of data was collected at RHIC and the LHC, probing hydrodynamics at the nucleon scale, the temperature dependence of the transport properties of quark-gluon plasma, the phase diagram of nuclear matter, the interaction of quarks and gluons at different scales and much more. This document, as part of the 2023 nuclear science long range planning process, was written to review the progress in hot QCD since the 2015 Long Range Plan for Nuclear Science, as well as highlight the realization of previous recommendations, and present opportunities for the next decade, building on the accomplishments and investments made in theoretical developments and the construction of new detectors. Furthermore, this document provides additional context to support the recommendations voted on at the Joint Hot and Cold QCD Town Hall Meeting, which are reported in a separate document.
Dostawca treści:: Repozytorium Uniwersytetu Jagiellońskiego

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