ИНФОРМАЦИОННЫЙ БЮЛЛЕТЕНЬ «СТАТЬИ» 50                          12.12.2016

 

С 17 - Вычислительная математика. Таблицы

1. Sharmazanashvili, A. Simulation Loop between CAD Systems, Geant4, and Geomodel: Implementation and Results / A.Sharmazanashvili, N.Tsutskiridze // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1116-1121. - Bibliogr.:7.

 

С 322 - Теория относительности

2. Hill, J.C. Kinematic Sunyaev-Zel'dovich Effect with Projected Fields: A Novel Probe of the Baryon Distribution with Planck, WMAP, and WISE Data / J.C.Hill, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.051301. - Bibliogr.:58.

http://dx.doi.org/10.1103/PhysRevLett.117.051301

3. Liu, X. Constraining f(R) Gravity Theory Using Weak Lensing Peak Statistics from the Canada-France-Hawaii-Telescope Lensing Survey / X.Liu, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.051101. - Bibliogr.:74.

http://dx.doi.org/10.1103/PhysRevLett.117.051101

4. Vitale, S. Multiband Gravitational-Wave Astronomy: Parameter Estimation and Tests of General Relativity with Space- and Ground-Based Detectors / S.Vitale // Physical Review Letters. – 2016. – Vol.117, No.5. – p.051102. - Bibliogr.:31.

http://dx.doi.org/10.1103/PhysRevLett.117.051102

С 323 - Квантовая механика

5. Bae, J. Operational Characterization of Divisibility of Dynamical Maps / J.Bae, D.Chruscinski // Physical Review Letters. – 2016. – Vol.117, No.5. – p.050403. - Bibliogr.:42.

http://dx.doi.org/10.1103/PhysRevLett.117.050403

6. Chapman, R.J. Experimental Demonstration of Self-Guided Quantum Tomography / R.J.Chapman, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.040402. - Bibliogr.:29.

http://dx.doi.org/10.1103/PhysRevLett.117.040402

7. Reiter, F. Scalable Dissipative Preparation of Many-Body Entanglement / F.Reiter, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.040501. - Bibliogr.:55.

http://dx.doi.org/10.1103/PhysRevLett.117.040501

С 323.5 - Теория взаимодействия частиц при высоких энергиях

8. Gninenko, S.N. Invisible K&sub(L) Decays in the SM Extensions / S.N.Gninenko, N.V.Krasnikov // Modern Physics Letters A [Electronic resource]. – 2016. – Vol.31, No.25. – p.1650142. - Bibliogr.:21.

http://dx.doi.org/10.1142/S021773231650142X

С 324.1 - Вторично- квантованные локальные теории взаимодействующих полей

9. Lashkari, N. Modular Hamiltonian for Excited States in Conformal Field Theory / N.Lashkari // Physical Review Letters. – 2016. – Vol.117, No.4. – p.041601. - Bibliogr.:21.

http://dx.doi.org/10.1103/PhysRevLett.117.041601

С 324.1г1 - Калибровочные поля на решетке

10. Yamamoto, A. Berry Phase in Lattice QCD / A.Yamamoto // Physical Review Letters. – 2016. – Vol.117, No.5. – p.052001. - Bibliogr.:19.

http://dx.doi.org/10.1103/PhysRevLett.117.052001

С 324.1д - Квантовая хромодинамика

11. Kurkela, A. Cool Quark Matter / A.Kurkela, A.Vuorinen // Physical Review Letters. – 2016. – Vol.117, No.4. – p.042501. - Bibliogr.:42.

http://dx.doi.org/10.1103/PhysRevLett.117.042501

С 324.1е - Суперсимметричные теории. Супергравитация. Суперструны

12. Piatek, M. Classical Irregular Blocks, Hill's Equation and PT-Symmetric Periodic Complex Potentials / M.Piatek, A.R.Pietrykowski // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.7. – p.131. - Bibliogr.:49.

http://dx.doi.org/10.1007/JHEP07(2016)131

С 325 - Статистическая физика и термодинамика

13. Bordag, M. Surface Plasmon on Graphene at Finite T / M.Bordag, I.G.Pirozhenko // International Journal of Modern Physics B [Electronic resource]. – 2016. – Vol.30, No.19. – p.1650120. - Bibliogr.:30.

http://dx.doi.org/10.1142/S0217979216501204

14. Gattenlohner, S. Levy Flights due to Anisotropic Disorder in Graphene / S.Gattenlohner, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.046603. - Bibliogr.:30.

http://dx.doi.org/10.1103/PhysRevLett.117.046603

15. Lee, K. Giant Frictional Drag in Double Bilayer Graphene Heterostructures / K.Lee, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.046803. - Bibliogr.:25.

http://dx.doi.org/10.1103/PhysRevLett.117.046803

16. Li, J.I.A. Negative Coulomb Drag in Double Bilayer Graphene / J.I.A.Li, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.046802. - Bibliogr.:33.

http://dx.doi.org/10.1103/PhysRevLett.117.046802

17. Алешин, А.Н. Полевые транзисторные структуры на основе поли(3-гексилтиофена), производных фуллеренов [60]PCBM, [70]PCBM и наночастиц никеля / А.Н.Алешин, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1818-1825. - Библиогр.:24.

http://journals.ioffe.ru/articles/viewPDF/43500

С 325.4 - Нелинейные системы. Хаос и синергетика. Фракталы

18. Lian, Y. SU(4) Skyrmions in the *n = *( 1 Quantum Hall State of Graphene / Y.Lian, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.056806. - Bibliogr.:27.

http://dx.doi.org/10.1103/PhysRevLett.117.056806

С 325.8 - Квантовые объекты низкой размерности (за исключением эффектов Холла)

19. Gullans, M.J. Sisyphus Thermalization of Photons in a Cavity-Coupled Double Quantum Dot / M.J.Gullans, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.056801. - Bibliogr.:54.

http://dx.doi.org/10.1103/PhysRevLett.117.056801

С 326 - Квантовая теория систем из многих частиц. Квантовая статистика

20. Ado, I.A. Anomalous Hall Effect in a 2D Rashba Ferromagnet / I.A.Ado, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.046601. - Bibliogr.:43.

http://dx.doi.org/10.1103/PhysRevLett.117.046601

21. Julku, A. Geometric Origin of Superfluidity in the Lieb-Lattice Flat Band / A.Julku, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.045303. - Bibliogr.:69.

http://dx.doi.org/10.1103/PhysRevLett.117.045303

22. Moskalets, M. Fractionally Charged Zero-Energy Single-Particle Excitations in a Driven Fermi Sea / M.Moskalets // Physical Review Letters. – 2016. – Vol.117, No.4. – p.046801. - Bibliogr.:56.

http://dx.doi.org/10.1103/PhysRevLett.117.046801

23. Qi, S. High-Temperature Quantum Anomalous Hall Effect in n−p Codoped Topological Insulators / S.Qi, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.056804. - Bibliogr.:51.

http://dx.doi.org/10.1103/PhysRevLett.117.056804

24. Qiao, Z. Anderson Localization from the Berry-Curvature Interchange in Quantum Anomalous Hall Systems / Z.Qiao, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.056802. - Bibliogr.:47.

http://dx.doi.org/10.1103/PhysRevLett.117.056802

25. Shi, H. Rashba Spin-Orbit Coupling, Strong Interactions, and the BCS-BEC Crossover in the Ground State of the Two-Dimensional Fermi Gas / H.Shi, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.040401. - Bibliogr.:53.

http://dx.doi.org/10.1103/PhysRevLett.117.040401

26. Znidaric, M. Diffusive and Subdiffusive Spin Transport in the Ergodic Phase of a Many-Body Localizable System / M.Znidaric, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.040601. - Bibliogr.:40.

http://dx.doi.org/10.1103/PhysRevLett.117.040601

С 33 а - Нанофизика. Нанотехнология

27. Конаков, Я.В. Влияние когерентных нановключений на стимулируемую напряжением миграцию малоугловых границ зерен в нанокомпозитах / Я.В.Конаков, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1757-1763. - Библиогр.:43.

http://journals.ioffe.ru/articles/viewPDF/43490

28. Старков, А.С. Мультикалорический эффект в пьезоэлектрическом слое / А.С.Старков, И.А.Старков // Физика твердого тела. – 2016. – Т.58, №9. – с.1739-1743. - Библиогр.:37.

http://journals.ioffe.ru/articles/viewPDF/43487

С 332 - Электромагнитные взаимодействия

29. Rublack, T. Production of Quasi Ellipsoidal Laser Pulses for Next Generation High Brightness Photoinjectors / T.Rublack, E.Syresin, [a.o.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.438-441. - Bibliogr.:7.

http://dx.doi.org/10.1016/j.nima.2015.12.004

С 341 а - Различные модели ядер

30. Белышев, С.С. Фотоядерные реакции на p-нуклидах &sup(106,108)Cd при верхней границе тормозного спектра 55,5 МэВ / С.С.Белышев, [др.] // Ядерная физика. – 2016. – Т.79, №5. – с.431-437. - Библиогр.:18.

http://dx.doi.org/10.1134/S1063778816050057

31. Воля, А. Количественные характеристики кластерных свойств в современных микроскопических ядерных моделях / А.Воля, Ю.М.Чувильский // Ядерная физика. – 2016. – Т.79, №5. – с.542-555. - Библиогр.:56.

http://dx.doi.org/10.1134/S1063778816040220

С 341 е - Ядерная астрофизика

32. Беляев, В.С. Перспективные направления исследований в области ядерной лабораторной астрофизики с использованием мощных лазеров / В.С.Беляев, [др.] // Ядерная физика. – 2016. – Т.79, №5. – с.438-455. - Библиогр.:55.

http://dx.doi.org/10.1134/S1063778816050045

С 341.1 - Радиоактивность

33. Martin-Albo, J. Sensitivity of NEXT-100 to Neutrinoless Double Beta Decay / J.Martin-Albo, Z.Tsamalaidze, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.5. – p.159. - Bibliogr.:75.

http://dx.doi.org/10.1007/JHEP05(2016)159

С 341.3 - Деление ядер

34. Olimov, K. Breakup of Oxygen Nucleus on Isotopes of Hydrogen and Nitrogen Nuclei in Collisions with Protons at 3.25 A GeV/c / K.Olimov, B.S.Yuldashev, [a.o.] // International Journal of Modern Physics E [Electronic resource]. – 2016. – Vol.25, No.8. – p.1650060. - Bibliogr.:16.

http://dx.doi.org/10.1142/S0218301316500609

35. Кадменский, С.Г. Асимметрии с различными Р- и Т-четностями в угловых распределениях продуктов двойного и тройного деления ориентированных ядер холодными поляризованными нейтронами и Т-инвариантность / С.Г.Кадменский, П.В.Кострюков // Ядерная физика. – 2016. – Т.79, №5. – с.556-563. - Библиогр.:16.

http://dx.doi.org/10.1134/S1063778816050100

36. Кадменский, С.Г. Последовательный характер низкоэнергетического тройного и четверного деления ядер / С.Г.Кадменский, А.О.Булычев // Ядерная физика. – 2016. – Т.79, №5. – с.564-569. - Библиогр.:28.

http://dx.doi.org/10.1134/S1063778816050112

С 342 - Прохождение частиц и гамма-квантов через вещество

37. Труханов, А.В. Кристаллическая структура, магнитные и микроволновые свойства твердых растворов BaFe&sub(12-x)Ga&sub(x)O&sub(19) (0.1 *{ x *{ 1.2) / А.В.Труханов, В.А.Турченко, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1733-38. - Библиогр.:20.

http://journals.ioffe.ru/articles/viewPDF/43486

С 343 - Ядерные реакции

38. Adam, J. Centrality Dependence of *q(2S) Suppression in p-Pb Collisions at *%s&sub(NN)=5.02 TeV / J.Adam, B.Batyunya, S.Grigoryan, L.Malinina, K.Mikhailov, P.Nomokonov, E.Rogochaya, A.Vodopyanov, S.Zaporozhets, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – p.050. - Bibliogr.:40.

http://dx.doi.org/10.1007/JHEP06(2016)050

39. Карпов, А.В. Сетевая база знаний NRV по ядерной физике низких энергий / А.В.Карпов, А.С.Деникин, А.П.Алексеев, В.И.Загребаев, В.А.Рачков, М.А.Науменко, В.В.Сайко // Ядерная физика. – 2016. – Т.79, №5. – с.520-532. - Библиогр.:42.

http://dx.doi.org/10.1134/S1063778816040141

40. Шматов, М.Л. Подавление цепной ядерной реакции синтеза на основе на реакции р + *1*1В вследствие торможения *a-частиц / М.Л.Шматов // Ядерная физика. – 2016. – Т.79, №5. – с.456-460. - Библиогр.:31.

http://dx.doi.org/10.1134/S106377881605015X

С 343 е - Ядерные реакции с тяжелыми ионами

41. Adam, J. Differential Studies of Inclusive J/*q and *q(2S) Production at Forward Rapidity in Pb-Pb Collisions at *%s&sub(NN)=2.76 TeV / J.Adam, B.Batyunya, S.Grigoryan, L.Malinina, K.Mikhailov, P.Nomokonov, E.Rogochaya, A.Vodopyanov, S.Zaporozhets, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.5. – p.179. - Bibliogr.:69.

http://dx.doi.org/10.1007/JHEP05(2016)179

42. Абрамов, Б.М. Выходы ядерных фрагментов во взаимодействиях ядер углерода с бериллиевой мишенью при 0.6 ГэВ/нуклон / Б.М.Абрамов, [др.] // Ядерная физика. – 2016. – Т.79, №5. – с.475-482. - Библиогр.:20.

http://dx.doi.org/10.1134/S1063778816050033

С 344.1 - Методы и аппаратура для регистрации элементарных частиц и фотонов

43. Dimitrov, L. Radiation Monitoring of the GEM Muon Detectors at CMS / L.Dimitrov, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.877-884. - Bibliogr.:12.

 

44. Gavrilov, V. Status of RDMS CMS Computing / V.Gavrilov, I.Golutvin, V.Korenkov, S.Shmatov, E.Tikhonenko, V.Zhiltsov, [a.o.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1108-1111. - Bibliogr.:11.

 

45. Kouzinopoulos, C.S. Performing Track Reconstruction at the ALICE TPC Using a Fast Hough Transform Method / C.S.Kouzinopoulos, P.Hristov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1020-1027. - Bibliogr.:10.

 

46. Kozyrev, A. A Comparative Study of LaBr&sub(3)(Ce*3*+) and CeBr&sub(3) Based Gamma-Ray Spectrometers for Planetary Remote Sensing Applications / A.Kozyrev, G.Timoshenko, V.Shvetsov, [a.o.] // Review of Scientific Instruments [Electronic resource]. – 2016. – Vol.87, No.8. – p.085112. - Bibliogr.:23.

http://dx.doi.org/10.1063/1.4958897

47. Krasnopevtsev, D.V. Study of ATLAS TRT Performance with Grid and Supercomputers / D.V.Krasnopevtsev, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1028-1035. - Bibliogr.:13.

 

48. Tsyganov, Yu.S. New Trends in the Development of "Active Correlations" Technique / Yu.S.Tsyganov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.898-904. - Bibliogr.:10.

 

49. Мокроусов, М.И. Возможности применения сцинтилляционных детекторов с полупроводниковым ФЭУ для регистрации космического нейтронного и гамма-излучения / М.И.Мокроусов // Ядерная физика. – 2016. – Т.79, №5. – с.468-474. - Библиогр.:5.

http://dx.doi.org/10.1134/S1063778816050136

С 344.3 - Ядерная электроника

50. Asbah, N. A Hardware Fast Tracker for the ATLAS Trigger / N.Asbah // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.842-847. - Bibliogr.:12.

 

51. Babkin, V.A. Status of the Front-End Electronics for the Time-of-Flight Measurements in the MPD Experiment / V.A.Babkin, M.G.Buryakov, V.M.Golovatyuk, S.V.Volgin, M.M.Rumyantsev // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.848-851. - Bibliogr.:7.

 

52. Batenkov, O.I. L0 Trigger Unit Prototype for BM@N Setup / O.I.Batenkov, D.N.Bogoslovski, V.Yu.Rogov, S.V.Sergeev, V.I.Yurevich // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.871-876. - Bibliogr.:5.

 

53. Mori, T. Phase-I Trigger Readout Electronics Upgrade of the ATLAS Liquid-Argon Calorimeters / T.Mori // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.860-870. - Bibliogr.:5.

 

54. Qin, Y. The Design and Performance of the ATLAS Inner Detector Trigger for Run 2 / Y.Qin // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.890-897. - Bibliogr.:13.

 

55. Subbotin, V.G. New Analog Electronics for the New Challenges in the Synthesis of Superheavy Elements / V.G.Subbotin, A.M.Zubareva, A.A.Voinov, A.N.Zubarev, L.Schlattauer // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.885-889. - Bibliogr.:12.

 

С 344.4б - Методы приготовления тонких пленок

56. Jeudy, V. Universal Pinning Energy Barrier for Driven Domain Walls in Thin Ferromagnetic Films / V.Jeudy, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.057201. - Bibliogr.:35.

http://dx.doi.org/10.1103/PhysRevLett.117.057201

57. Абдуллаев, Н.А. Слабая антилокализация в тонких пленках твердого раствора Bi&sub(2)Te&sub(2.7)Se&sub(0.3) / Н.А.Абдуллаев, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1806-1811. - Библиогр.:28.

http://journals.ioffe.ru/articles/viewPDF/43498

58. Комолов, А.С. Электронная структура зоны проводимости пограничной области сверхтонких пленок замещенных перилен-дикарбоксимидов и поверхности оксида германия / А.С.Комолов, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1836-1840. - Библиогр.:26.

http://journals.ioffe.ru/articles/viewPDF/43502

59. Лазарева, Н.Л. Преобразование микроструктуры и люминесцентных характеристик пленок LiF в процессе отжига / Н.Л.Лазарева, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1714-1718. - Библиогр.:16.

http://journals.ioffe.ru/articles/viewPDF/43483

С 345 - Ускорители заряженных частиц

60. Andreev, V. TANGO Standard Software to Control the Nuclotron Beam Slow Extraction / V.Andreev, V.Volkov, E.Gorbachev, V.Isadov, A.Kirichenko, S.Romanov, G.S.Sedykh // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.951-956. - Bibliogr.:6.

 

61. Bashashin, M.V. NICA Project Management Information System / M.V.Bashashin, D.V.Kekelidze, S.A.Kostromin, V.V.Korenkov, S.V.Kuniaev, V.V.Morozov, Yu.K.Potrebenikov, G.V.Trubnikov, A.V.Philippov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.969-973. - Bibliogr.:3.

 

62. Dorda, U. SINBAD - The Accelerator R&D Facility Under Construction at DESY / U.Dorda, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.233-236. - Bibliogr.:16.

http://dx.doi.org/10.1016/j.nima.2016.01.067

63. Gorbachev, E.V. Development of Tools for Real-Time Betatron Tune Measurements at the Nuclotron / E.V.Gorbachev, A.E.Kirichenko, D.V.Monakhov, S.V.Romanov, V.I.Volkov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.918-921. - Bibliogr.:7.

 

64. Gorbachev, E.V. The Nuclotron and NICA Control System Development Status / E.V.Gorbachev, V.A.Andreev, A.E.Kirichenko, D.V.Monakhov, S.V.Romanov, T.V.Rukoyatkina, G.S.Sedykh, V.I.Volkov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.905-912. - Bibliogr.:7.

 

65. Guidoboni, G. How to Reach a Thousand-Second in-Plane Polarization Lifetime with 0.97−GeV/c Deuterons in a Storage Ring / G.Guidoboni, S.Dymov, A.Kulikov, G.Macharashvili, V.Shmakova, A.Silenko, Yu.Uzikov, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.054801. - Bibliogr.:29.

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66. Motycak, S. A New Beam Diagnostic System for the MASHA Setup / S.Motycak, A.M.Rodin, A.S.Novoselov, A.V.Podshibyakin, L.Krupa, A.V.Belozerov, V.Yu.Vedeneyev, A.V.Gulyaev, A.V.Gulyaeva, J.Kliman, V.S.Salamatin, S.V.Stepantsov, E.V.Chernysheva, S.A.Yukhimchuk, A.B.Komarov, D.Kamas // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.922-928. - Bibliogr.:7.

 

67. Schmidt, J.S. Status of the Proton and Electron Transfer Lines for the AWAKE Experiment at CERN / J.S.Schmidt, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.58-62. - Bibliogr.:10.

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68. Tsakanov, V.M. AREAL Low Energy Electron Beam Applications in Life and Materials Sciences / V.M.Tsakanov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.248-253. - Bibliogr.:32.

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69. Yoffe, S.R. Cooling of Relativistic Electron Beams in Intense Laser Pulses: Chirps and Radiation / S.R.Yoffe, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.243-247. - Bibliogr.:30.

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С 345 л - Новые методы ускорения

70. Adli, E. Progress of Plasma Wakefield Self-Modulation Experiments at FACET / E.Adli, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.334-338. - Bibliogr.:19.

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71. Adli, E. Transverse Oscillations in Plasma Wakefield Experiments at FACET / E.Adli, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.94-98. - Bibliogr.:13.

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72. Ahmed, H. Investigations of Ultrafast Charge Dynamics in Laser-Irradiated Targets by a Self Probing Technique Employing Laser Driven Protons / H.Ahmed, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.172-175. - Bibliogr.:21.

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73. Akhter, T. Self-Modulated Dynamics of a Relativistic Charged Particle Beam in Plasma Wake Field Excitation / T.Akhter, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.426-431. - Bibliogr.:21.

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74. Altana, C. Investigation of Ion Acceleration Mechanism Through Laser-Matter Interaction in Femtosecond Domain / C.Altana, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.159-162. - Bibliogr.:19.

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75. Anania, M.P. Plasma Production for Electron Acceleration by Resonant Plasma Wave / M.P.Anania, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.254-259. - Bibliogr.:17.

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76. Audet, T.L. Electron Injector for Compact Staged High Energy Accelerator / T.L.Audet, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.304-308. - Bibliogr.:17.

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77. Beck, A. Load Management Strategy for Particle-In-Cell Simulations in High Energy Particle Acceleration / A.Beck, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.418-421. - Bibliogr.:18.

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78. Bisesto, F.G. Laser–Capillary Interaction for the EXIN Project / F.G.Bisesto, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.309-313. - Bibliogr.:15.

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79. Borghesi, M. Summary of Working Group 2: Ion Beams from Plasmas / M.Borghesi, U.Schramm // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.137-140. - Bibliogr.:29.

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80. Cros, B. Summary of WG5: High-Gradient Plasma Structures and Advanced Beam Diagnostics / B.Cros, E.Chiadroni // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.301-303.

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81. Fedele, R. The Concept of Coupling Impedance in the Self-Consistent Plasma Wake Field Excitation / R.Fedele, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.397-402. - Bibliogr.:15.

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82. Filippi, F. Plasma Density Characterization at SPARC_LAB Through Stark Broadening of Hydrogen Spectral Lines / F.Filippi, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.326-329. - Bibliogr.:12.

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83. Fiore, G. A "Slingshot" Laser-Driven Acceleration Mechanism of Plasma Electrons / G.Fiore, S.De Nicola // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.104-108. - Bibliogr.:12.

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84. Gatti, G. X-Band Accelerator Structures: On Going R&D at the INFN / G.Gatti, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.206-212. - Bibliogr.:40.

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85. Gizzi, L.A. Role of Laser Contrast and Foil Thickness in Target Normal Sheath Acceleration / L.A.Gizzi, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.144-148. - Bibliogr.:17.

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86. Golovanov, A.A. Piecewise-Homogeneous Model for Electron Side Injection into Linear Plasma Waves / A.A.Golovanov, I.Yu.Kostyukov // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.392-396. - Bibliogr.:16.

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87. Gschwendtner, E. AWAKE, The Advanced Proton Driven Plasma Wakefield Acceleration Experiment at CERN / E.Gschwendtner, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.76-82. - Bibliogr.:23.

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88. Hachmann, M. Design and Characterization of Permanent Magnetic Solenoids for REGAE / M.Hachmann, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.270-273. - Bibliogr.:8.

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89. Hansson, M. Injection of Electrons by Colliding Laser Pulses in a Laser Wakefield Accelerator / M.Hansson, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.99-103. - Bibliogr.:20.

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90. Ivanyan, M.I. High Frequency Single Mode Traveling Wave Structure for Particle Acceleration / M.I.Ivanyan, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.187-189. - Bibliogr.:11.

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91. Jovanovic, D. Semi-Analytical Fluid Study of the Laser Wake Field Excitation in the Strong Intensity Regime / D.Jovanovic, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.413-417. - Bibliogr.:13.

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92. Kalmykov, S.Y. Customizable Electron Beams from Optically Controlled Laser Plasma Acceleration for *g-Ray Sources Based on Inverse Thomson Scattering / S.Y.Kalmykov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.52-57. - Bibliogr.:54.

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93. Khojoyan, M. Transport Studies of LPA Electron Beam Towards the FEL Amplification at COXINEL / M.Khojoyan, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.260-264. - Bibliogr.:38.

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94. King, M. Ion Acceleration and Plasma Jet Formation in Ultra-Thin Foils Undergoing Expansion and Relativistic Transparency / M.King, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.163-166. - Bibliogr.:17.

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95. Kluge, T. Controlled Electron Bunch Generation in the Few-Cycle Ultra-Intense Laser–Solid Interaction Scenario / T.Kluge, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.376-377. - Bibliogr.:7.

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96. Kniaziev, R.R. Influence of Emittance on Transverse Dynamics of Accelerated Bunches in the Plasma–Dielectric Wakefield Accelerator / R.R.Kniaziev, G.V.Sotnikov // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.121-124. - Bibliogr.:19.

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97. Kohler, A. Single-Shot Betatron Source Size Measurement from a Laser-Wakefield Accelerator / A.Kohler, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.265-269. - Bibliogr.:19.

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98. Kononenko, O. 2D Hydrodynamic Simulations of a Variable Length Gas Target for Density Down-Ramp Injection of Electrons into a Laser Wakefield Accelerator / O.Kononenko, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.125-129. - Bibliogr.:13.

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99. Lee, P. Modeling Laser-Driven Electron Acceleration Using WARP with Fourier Decomposition / P.Lee, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.358-362. - Bibliogr.:8.

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100. Lindstrom, C.A. Staging Optics Considerations for a Plasma Wakefield Acceleration Linear Collider / C.A.Lindstrom, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.224-228. - Bibliogr.:7.

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101. Lishilin, O. First Results of the Plasma Wakefield Acceleration Experiment at PITZ / O.Lishilin, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.37-42. - Bibliogr.:24.

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102. Lotov, K.V. Summary of Working Group 6: Theory and Simulations / K.V.Lotov, J.-L.Vay // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.348-349. - Bibliogr.:19.

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103. Malka, V. Summary of Working Group 1: Electron Beam from Plasmas / V.Malka, E.Gschwendtner // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.30-32.

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104. Marchetti, B. Electron-Beam Manipulation Techniques in the SINBAD Linac for External Injection in Plasma Wake-Field Acceleration / B.Marchetti, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.278-283. - Bibliogr.:35.

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105. Marocchino, A. Efficient Modeling of Plasma Wakefield Acceleration in Quasi-Non-Linear-Regimes with the Hybrid Code Architect / A.Marocchino, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.386-391. - Bibliogr.:36.

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106. Maslov, V.I. Dynamics of Electron Bunches at the Laser–Plasma Interaction in the Bubble Regime / V.I.Maslov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.422-425. - Bibliogr.:23.

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107. Massimo, F. Electromagnetic Self-Consistent Field Initialization and Fluid Advance Techniques for Hybrid-Kinetic PWFA Code Architect / F.Massimo, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.378-382. - Bibliogr.:20.

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108. McNeur, J. Laser-Driven Acceleration of Subrelativistic Electrons Near a Nanostructured Dielectric Grating: From Acceleration Via Higher Spatial Harmonics to Necessary Elements of a Dielectric Accelerator / J.McNeur, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.50-51. - Bibliogr.:7.

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109. Mehrling, T.J. Efficient Numerical Modelling of the Emittance Evolution of Beams with Finite Energy Spread in Plasma Wakefield Accelerators / T.J.Mehrling, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.367-371. - Bibliogr.:34.

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110. Muoio, A. Mono-Energetic Ions Emission by Nanosecond Laser Solid Target Irradiation / A.Muoio, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.141-143. - Bibliogr.:14.

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111. Nie, Y.C. Potential Applications of the Dielectric Wakefield Accelerators in the SINBAD Facility at DESY / Y.C.Nie, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.183-186. - Bibliogr.:30.

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112. Obcemea, C. Potential Clinical Impact of Laser-Accelerated Beams in Cancer Ion Therapy / C.Obcemea // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.149-152. - Bibliogr.:22.

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113. Onishchenko, I.N. Investigations of the Concept of a Multibunch Dielectric Wakefield Accelerator / I.N.Onishchenko, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.199-205. - Bibliogr.:13.

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114. Oz, E. An Accurate Rb Density Measurement Method for a Plasma Wakefield Accelerator Experiment Using a Novel Rb Reservoir / E.Oz, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.321-325. - Bibliogr.:11.

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115. Palla, D. Comparison of Self-Injection Thresholds in He and N&sub(2) and Role of Self-Focusing in LWFA / D.Palla, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.408-412. - Bibliogr.:22.

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116. Pauw, V. Particle-In-Cell Simulation of Laser Irradiated Two-Component Microspheres in 2 and 3 Dimensions / V.Pauw, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.372-375. - Bibliogr.:15.

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117. Petrenko, A. Numerical Studies of Electron Acceleration Behind Self-Modulating Proton Beam in Plasma with a Density Gradient / A.Petrenko, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.63-66. - Bibliogr.:19.

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118. Pogorelsky, I.V. BESTIA - The Next Generation Ultra-Fast CO&sub(2) Laser for Advanced Accelerator Research / I.V.Pogorelsky, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.432-437. - Bibliogr.:9.

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119. Pugachev, L.P. Acceleration of Electrons Under the Action of Petawatt-Class Laser Pulses Onto Foam Targets / L.P.Pugachev, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.88-93. - Bibliogr.:32.

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120. Romano, F. The ELIMED Transport and Dosimetry Beamline for Laser-Driven Ion Beams / F.Romano, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.153-158. - Bibliogr.:40.

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121. Romeo, S. Beam Dynamics in Resonant Plasma Wakefield Acceleration at SPARC_LAB / S.Romeo, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.109-112. - Bibliogr.:17.

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122. Rossi, A.R. Stability Study for Matching in Laser Driven Plasma Acceleration / A.R.Rossi, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.67-72. - Bibliogr.:26.

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123. Schroeder, C.B. Laser-Plasma-Based Linear Collider Using Hollow Plasma Channels / C.B.Schroeder, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.113-116. - Bibliogr.:21.

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124. Shallo, R.J. Generation of Laser Pulse Trains for Tests of Multi-Pulse Laser Wakefield Acceleration / R.J.Shallo, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.383-385. - Bibliogr.:10.

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125. Shchelkunov, S.V. High Transformer Ratio of Multi-Channel Dielectric Wakefield Structures / S.V.Shchelkunov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.213-220. - Bibliogr.:23.

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126. Shchelkunov, S.V. Real-Time Diagnostic for Charging and Damage of Dielectrics in Accelerators / S.V.Shchelkunov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.194-198. - Bibliogr.:11.

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127. Sinigardi, S. Numerical Simulations of Recent Proton Acceleration Experiments with Sub-100 TW Laser Systems / S.Sinigardi // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.167-171. - Bibliogr.:10.

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128. Sosedkin, A.P. LCODE: A Parallel Quasistatic Code for Computationally Heavy Problems of Plasma Wakefield Acceleration / A.P.Sosedkin, K.V.Lotov // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.350-353. - Bibliogr.:22.

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129. Tanjia, F. Formation and Stability of a Hollow Electron Beam in the Presence of a Plasma Wake Field Driven by an Ultra-Short Electron Bunch / F.Tanjia, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.130-136. - Bibliogr.:12.

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130. Teryaev, V.E. Multi-Beam Linear Accelerator EVT / V.E.Teryaev, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.221-223. - Bibliogr.:4.

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131. Tsakanov, V.M. AREAL Test Facility for Advanced Accelerator and Radiation Source Concepts / V.M.Tsakanov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.284-290. - Bibliogr.:37.

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132. Turner, M. Indirect Self-Modulation Instability Measurement Concept for the AWAKE Proton Beam / M.Turner, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.314-317. - Bibliogr.:12.

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133. Vay, J.-L. Recent Advances in High-Performance Modeling of Plasma-Based Acceleration Using the Full PIC Method / J.-L.Vay, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.353-357. - Bibliogr.:41.

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134. Villa, F. Laser Pulse Shaping for High Gradient Accelerators / F.Villa, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.446-451. - Bibliogr.:24.

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135. Weikum, M.K. Generation of Attosecond Electron Bunches in a Laser-Plasma Accelerator Using a Plasma Density Upramp / M.K.Weikum, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.33-36. - Bibliogr.:18.

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136. Wittig, G. Electron Beam Manipulation, Injection and Acceleration in Plasma Wakefield Accelerators by Optically Generated Plasma Density Spikes / G.Wittig, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.83-87. - Bibliogr.:31.

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137. Wuensch, W. Summary of the Working Group 3: Electron Beams from Electromagnetic Structures, Including Dielectric and Laser-Driven Structures / W.Wuensch, P.Hommelhoff // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.181-182.

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138. Xia, G. Plasma Wakefield Acceleration at CLARA Facility in Daresbury Laboratory / G.Xia, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.43-49. - Bibliogr.:36.

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139. Zholents, A. A Preliminary Design of the Collinear Dielectric Wakefield Accelerator / A.Zholents, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.190-193. - Bibliogr.:13.

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140. Zhu, J. Matching Sub-fs Electron Bunches for Laser-Driven Plasma Acceleration at SINBAD / J.Zhu, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.229-232. - Bibliogr.:18.

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С 345 о - Электронная и ионная оптика. Формирование и анализ пучков

141. Cianchi, A. Observations and Diagnostics in High Brightness Beams / A.Cianchi, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.343-347. - Bibliogr.:65.

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142. Hachmann, M. Measurement of Ultra Low Transverse Emittance at REGAE / M.Hachmann, K.Flottmann // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.318-320. - Bibliogr.:8.

http://dx.doi.org/10.1016/j.nima.2016.01.065

143. Shpakov, V. Betatron Radiation Based Diagnostics for Plasma Wakefield Accelerated Electron Beams at the SPARC_LAB Test Facility / V.Shpakov, [et al.] // Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – p.330-333. - Bibliogr.:29.

http://dx.doi.org/10.1016/j.nima.2016.02.074

С 345 с - Магнитные поля и сверхпроводящие магниты. Магнитные измерения

144. Filippov, Yu.P. A Method for Calibrating Cryogenic Void Fraction RF-Sensors Having a Round Cross-Section and Estimating Their Accuracy / Yu.P.Filippov, I.D.Kakorin // Cryogenics [Electronic Resource]. – 2016. – Vol.79. – p.63-73. - Bibliogr.:17.

http://dx.doi.org/10.1016/j.cryogenics.2016.07.015

145. Gorbachev, E.V. The Thermometry System of Superconducting Magnets Test Bench for the NICA Accelerator Complex / E.V.Gorbachev, A.E.Kirichenko, G.S.Sedykh, V.I.Volkov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.939-944. - Bibliogr.:4.

 

С 346 - Элементарные частицы

146. Currie, J. Precise QCD Predictions for the Production of Dijet Final States in Deep Inelastic Scattering / J.Currie, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.042001. - Bibliogr.:38.

http://dx.doi.org/10.1103/PhysRevLett.117.042001

С 346.1 - Нейтрино

147. Хрущев, В.В. Осцилляционные характеристики активных и стерильных нейтрино и нейтринные аномалии на малых расстояниях / В.В.Хрущев, [др.] // Ядерная физика. – 2016. – Т.79, №5. – с.483-496. - Библиогр.:52.

http://dx.doi.org/10.1134/S1063778816050124

С 346.2 - Нуклоны и антинуклоны

148. Aaboud, M. Measurement of the Relative Width Difference of the B*0-B^- *0 System with the ATLAS Detector / M.Aaboud, F.Ahmadov, I.N.Aleksandrov, V.A.Bednyakov, I.R.Boyko, I.A.Budagov, G.A.Chelkov, A.Cheplakov, M.V.Chizhov, D.V.Dedovich, M.Demichev, A.Gongadze, M.I.Gostkin, N.Huseynov, N.Javadov, S.N.Karpov, Z.M.Karpova, E.Khramov, U.Kruchonak, V.Kukhtin, E.Ladygin, V.Lyubushkin, I.A.Minashvili, M.Mineev, V.D.Peshekhonov, E.Plotnikova, I.N.Potrap, V.Pozdnyakov, N.A.Rusakovich, R.Sadykov, A.Sapronov, M.Shiyakova, A.Soloshenko, V.B.Vinogradov, I.Yeletskikh, A.Zhemchugov, N.I.Zimine, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – p.081. - Bibliogr.:23.

http://dx.doi.org/10.1007/JHEP06(2016)081

149. Aaboud, M. Search for New Phenomena in Events with a Photon and Missing Transverse Momentum in pp Collisions at *%s=13 TeV with the ATLAS Detector / M.Aaboud, F.Ahmadov, I.N.Aleksandrov, V.A.Bednyakov, I.R.Boyko, I.A.Budagov, G.A.Chelkov, A.Cheplakov, M.V.Chizhov, D.V.Dedovich, M.Demichev, A.Gongadze, M.I.Gostkin, N.Huseynov, N.Javadov, S.N.Karpov, Z.M.Karpova, E.Khramov, U.Kruchonak, V.Kukhtin, E.Ladygin, V.Lyubushkin, I.A.Minashvili, M.Mineev, V.D.Peshekhonov, E.Plotnikova, I.N.Potrap, V.Pozdnyakov, N.A.Rusakovich, R.Sadykov, A.Sapronov, M.Shiyakova, A.Soloshenko, V.B.Vinogradov, I.Yeletskikh, A.Zhemchugov, N.I.Zimine, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – p.059. - Bibliogr.:75.

http://dx.doi.org/10.1007/JHEP06(2016)059

150. Aad, G. A Search for Top Squarks with R-Parity-Violating Decays to All-Hadronic Final States with the ATLAS Detector in *%s=8 TeV Proton-Proton Collisions / G.Aad, F.Ahmadov, I.N.Aleksandrov, V.A.Bednyakov, I.R.Boyko, I.A.Budagov, G.A.Chelkov, A.Cheplakov, M.V.Chizhov, D.V.Dedovich, M.Demichev, M.I.Gostkin, N.Huseynov, N.Javadov, S.N.Karpov, Z.M.Karpova, E.Khramov, V.M.Kotov, U.Kruchonak, V.Kukhtin, E.Ladygin, I.A.Minashvili, M.Mineev, V.D.Peshekhonov, E.Plotnikova, I.N.Potrap, V.Pozdnyakov, N.A.Rusakovich, R.Sadykov, A.Sapronov, M.Shiyakova, A.Soloshenko, V.B.Vinogradov, I.Yeletskikh, A.Zhemchugov, N.I.Zimine, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – p.067. - Bibliogr.:100.

http://dx.doi.org/10.1007/JHEP06(2016)067

151. Aad, G. Identification of High Transverse Momentum Top Quarks in pp Collisions at *%s=8 TeV with the ATLAS Detector / G.Aad, F.Ahmadov, I.N.Aleksandrov, V.A.Bednyakov, I.R.Boyko, I.A.Budagov, G.A.Chelkov, A.Cheplakov, M.V.Chizhov, D.V.Dedovich, M.Demichev, M.I.Gostkin, N.Huseynov, N.Javadov, S.N.Karpov, Z.M.Karpova, E.Khramov, V.M.Kotov, U.Kruchonak, V.Kukhtin, E.Ladygin, I.A.Minashvili, M.Mineev, V.D.Peshekhonov, E.Plotnikova, I.N.Potrap, V.Pozdnyakov, N.A.Rusakovich, R.Sadykov, A.Sapronov, M.Shiyakova, A.N.Sisakyan, A.Soloshenko, V.B.Vinogradov, I.Yeletskikh, A.Zhemchugov, N.I.Zimine, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – p.093. - Bibliogr.:96.

http://dx.doi.org/10.1007/JHEP06(2016)093

152. Khachatryan, V. Search for Direct Pair Production of Scalar Top Quarks in the Single- and Dilepton Channels in Proton-Proton Collisions at *%s=8 TeV / V.Khachatryan, S.Afanasiev, P.Bunin, M.Finger, M.Finger Jr., M.Gavrilenko, I.Golutvin, I.Gorbunov, A.Kamenev, V.Karjavin, A.Lanev, A.Malakhov, V.Matveev, P.Moisenz, V.Palichik, V.Perelygin, S.Shmatov, S.Shulha, N.Skatchkov, V.Smirnov, Z.Tsamalaidze, A.Zarubin, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.7. – p.027. - Bibliogr.:48.

http://dx.doi.org/10.1007/JHEP07(2016)027

153. Khachatryan, V. Search for Resonant Production of High-Mass Photon Pairs in Proton-Proton Collisions at *%s=8 and 13 TeV / V.Khachatryan, S.Afanasiev, P.Bunin, M.Finger, M.Finger Jr., M.Gavrilenko, I.Golutvin, I.Gorbunov, A.Kamenev, V.Karjavin, A.Lanev, A.Malakhov, V.Matveev, P.Moisenz, V.Palichik, V.Perelygin, S.Shmatov, S.Shulha, N.Skatchkov, V.Smirnov, Z.Tsamalaidze, N.Voytishin, A.Zarubin, [a.o.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.051802. - Bibliogr.:44.

http://dx.doi.org/10.1103/PhysRevLett.117.051802

154. Khachatryan, V. Search for the Associated Production of a Higgs Boson with a Single Top Quark in Proton-Proton Collisions at *%s=8 TeV / V.Khachatryan, S.Afanasiev, P.Bunin, M.Finger, M.Finger Jr., M.Gavrilenko, I.Golutvin, I.Gorbunov, A.Kamenev, V.Karjavin, V.Konoplyanikov, A.Lanev, A.Malakhov, V.Matveev, P.Moisenz, V.Palichik, V.Perelygin, S.Shmatov, S.Shulha, N.Skatchkov, V.Smirnov, Z.Tsamalaidze, A.Zarubin, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – p.177. - Bibliogr.:57.

http://dx.doi.org/10.1007/JHEP06(2016)177

С 346.4 - Пи-мезоны

155. Ибраева, Е.Т. Сравнительный анализ рассеяния протонов и *p-мезонов на изотопах &sup(6,8)Не в глауберовской теории / Е.Т.Ибраева, О.Имамбеков // Ядерная физика. – 2016. – Т.79, №5. – с.533-541. - Библиогр.:44.

http://dx.doi.org/10.1134/S1063778816040128

С 346.6 - Резонансы и новые частицы

156. Aad, G. Search for the Standard Model Higgs Boson Decaying into bb^-   Produced in Association with Top Quarks Decaying Hadronically in pp Collisions at *%s=8 TeV with the ATLAS Detector / G.Aad, F.Ahmadov, I.N.Aleksandrov, V.A.Bednyakov, I.R.Boyko, I.A.Budagov, G.A.Chelkov, A.Cheplakov, M.V.Chizhov, D.V.Dedovich, M.Demichev, A.Gongadze, M.I.Gostkin, N.Huseynov, N.Javadov, S.N.Karpov, Z.M.Karpova, E.Khramov, U.Kruchonak, V.Kukhtin, E.Ladygin, V.Lyubushkin, I.A.Minashvili, M.Mineev, V.D.Peshekhonov, E.Plotnikova, I.N.Potrap, V.Pozdnyakov, N.A.Rusakovich, R.Sadykov, A.Sapronov, M.Shiyakova, A.Soloshenko, V.B.Vinogradov, I.Yeletskikh, A.Zhemchugov, N.I.Zimine, [a.o.] // Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.5. – p.160. - Bibliogr.:80.

http://dx.doi.org/10.1007/JHEP05(2016)160

157. Ablikim, M. Observation of an Anomalous Line Shape of the *h'*p*+*p*- Mass Spectrum near the pp^-   Mass Threshold in J/*q*>*g*h'*p*+*p*- / M.Ablikim, E.Boger, I.Boyko, G.Chelkov, D.Dedovich, I.Denysenko, O.Fedorov, Y.Nefedov, A.Sarantsev, A.Zhemchugov, [a.o.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.042002. - Bibliogr.:27.

http://dx.doi.org/10.1103/PhysRevLett.117.042002

С 347 - Космические лучи

158. Grebenyuk, V. Ground-Based Complex for Checking the Optical System of the TUS Experiment / V.Grebenyuk, V.Boreiko, N.Gorbunov, M.Lavrova, B.Sabirov, A.Tkachenko, L.Tkachev, [a.o.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.913-917. - Bibliogr.:10.

 

С 348 - Ядерные реакторы. Реакторостроение

159. Pepelyshev, Yu.N. Application of Cluster Analysis and Autoregressive Neural Networks for the Noise Diagnostics of the IBR-2M Reactor / Yu.N.Pepelyshev, Ts.Tsogtsaikhan, G.A.Ososkov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1089-1094. - Bibliogr.:11.

 

С 353 - Физика плазмы

160. Gursoy, U. Holographic Equilibration of Nonrelativistic Plasmas / U.Gursoy, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.5. – p.051601. - Bibliogr.:33.

http://dx.doi.org/10.1103/PhysRevLett.117.051601

161. Zhong, W.L. Observation of Double Impurity Critical Gradients for Electromagnetic Turbulence Excitation in Tokamak Plasmas / W.L.Zhong, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.045001. - Bibliogr.:34.

http://dx.doi.org/10.1103/PhysRevLett.117.045001

С 36 - Физика твердого тела

162. He, J. Ultralow Thermal Conductivity in Full Heusler Semiconductors / J.He, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.046602. - Bibliogr.:57.

http://dx.doi.org/10.1103/PhysRevLett.117.046602

163. Kruger, C. Curling Liquid Crystal Microswimmers: A Cascade of Spontaneous Symmetry Breaking / C.Kruger, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.048003. - Bibliogr.:33.

http://dx.doi.org/10.1103/PhysRevLett.117.048003

164. Берзин, А.А. Механизм возникновения дальнего порядка, индуцированного случайными полями: эффективная анизотропия, созданная дефектами / А.А.Берзин, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1783-1785. - Библиогр.:9.

http://journals.ioffe.ru/articles/viewPDF/43494

165. Захлевных, А.Н. Ориентационные переходы в антиферромагнитных жидких кристаллах / А.Н.Захлевных, Д.А.Петров // Физика твердого тела. – 2016. – Т.58, №9. – с.1841-1850. - Библиогр.:25.

http://journals.ioffe.ru/articles/viewPDF/43503

С 44 - Аналитическая химия

166. Karetnikov, M.D. Multidetector System for Nanosecond Tagged Neutron Technology Based on Hardware Selection of Events / M.D.Karetnikov, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.852-859. - Bibliogr.:5.

 

С 45 а - Термодинамические величины элементов и соединений

167. Денисова, Л.Т. Высокотемпературная теплоемкость ортованадатов Ce&sub(1-x)Bi&sub(x)VO&sub(4) / Л.Т.Денисова, [др.] // Физика твердого тела. – 2016. – Т.58, №9. – с.1867-1870. - Библиогр.:21.

http://journals.ioffe.ru/articles/viewPDF/43507

Ц 84 - Вычислительная техника и программирование

168. Levchanovskiy, F.V. DeLiDAQ-2D - a New Data Acquisition System for Position-Sensitive Neutron Detectors with Delay-Line Readout / F.V.Levchanovskiy, S.M.Murashkevich // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.929-933. - Bibliogr.:2.

 

169. Novoselov, A.S. Data Acquisition System for the Focal-Plane Detector of the Mass Separator MASHA / A.S.Novoselov, A.M.Rodin, S.Motycak, A.V.Podshibyakin, L.Krupa, A.V.Belozerov, V.Yu.Vedeneyev, A.V.Gulyaev, A.V.Gulyaeva, J.Kliman, V.S.Salamatin, S.V.Stepantsov, E.V.Chernysheva, S.A.Yukhimchuk, A.B.Komarov, D.Kamas // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.934-938. - Bibliogr.:2.

 

170. Zamriy, V.N. Host-Based Data Acquisition System to Control Pulsed Facilities of the Accelerator / V.N.Zamriy // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.945-950. - Bibliogr.:3.

 

Ц 84 а - Вычислительные машины в целом

171. Karlov, A.A. Virtualization in Education: Information Security Lab in Your Hands / A.A.Karlov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1000-1005. - Bibliogr.:8.

 

172. Tokareva, N.A. E-Learning as a Technological Tool to Meet the Requirements of Occupational Standards in Training of IT Specialists / N.A.Tokareva, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1112-1115. - Bibliogr.:3.

 

Ц 84 а2 - Многомашинные комплексы вычислительных средств. Вычислительные системы и сети. Параллельные вычисления. Квантовые компьютеры

173. Alekseev, A.A. Efficient Data Management Tools for the Heterogeneous Big Data Warehouse / A.A.Alekseev, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1069-1073. - Bibliogr.:4.

 

174. Astakhov, N.S. JINR Tier-1 Centre for the CMS Experiment at LHC / N.S.Astakhov, A.S.Baginyan, S.D.Belov, A.G.Dolbilov, A.O.Golunov, I.N.Gorbunov, N.I.Gromova, I.S.Kadochnikov, I.A.Kashunin, V.V.Korenkov, V.V.Mitsyn, I.S.Pelevanyuk, S.V.Shmatov, T.A.Strizh, E.A.Tikhonenko, V.V.Trofimov, N.N.Voitishin, V.E.Zhiltsov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1103-1107. - Bibliogr.:12
.

 

175. Balashov, N. Optimization of Over-Provisioned Clouds / N.Balashov, A.Baranov, V.Korenkov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.957-961. - Bibliogr.:5.

 

176. Baranov, A.V. JINR Cloud Infrastructure Evolution / A.V.Baranov, N.A.Balashov, N.A.Kutovskiy, R.N.Semenov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1046-1050. - Bibliogr.:11.

 

177. Belov, S.D. BES-III Distributed Computing Status / S.D.Belov, V.V.Korenkov, I.Pelevanyuk, V.V.Trofimov, A.V.Uzhinskiy, A.S.Zhemchugov, [a.o.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1084-1088. - Bibliogr.:17.

 

178. Bogatencov, P.P. Scientific Computing Infrastructure and Services in Moldova / P.P.Bogatencov, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1064-1068. - Bibliogr.:4.

 

179. De, K. Integration of PanDA Workload Management System with Supercomputers / K.De, D.A.Oleynik, [a.o.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1010-1019. - Bibliogr.:10.

 

180. Demichev, A.P. Design of Web Platform for Science and Engineering in the Model of Open Market / A.P.Demichev, A.P.Kryukov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1036-1040. - Bibliogr.:7.

 

181. Korenkov, V.V. Simulation Concept of NICA-MPD-SPD TIER0-TIER1 Computing Facilities / V.V.Korenkov, A.V.Nechaevskiy, G.A.Ososkov, D.I.Pryahina, V.V.Trofimov, A.V.Uzhinskiy // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1074-1083. - Bibliogr.:16.

 

182. Kundrat, J. Grids and Clouds in the Czech NGI / J.Kundrat, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1041-1045. - Bibliogr.:26.

 

183. Kvatadze, R. Network and Computing Infrastructure for Scientific Applications in Georgia / R.Kvatadze, Z.Modebadze // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1058-1063. - Bibliogr.:2.

 

184. Lamanna, M. Large-Scale Data Services for Science: Present and Future Challenges / M.Lamanna // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1051-1057. - Bibliogr.:9.

 

185. Petrosyan, A.Sh. PanDA for COMPASS at JINR / A.Sh.Petrosyan // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1095-1098. - Bibliogr.:10.

 

186. Slepov, I.P. Creating Interactive Video Broadcasting System for VBLHEP / I.P.Slepov // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1099-1102. - Bibliogr.:4.

 

Ц 840 г - Программирование АСУ

187. Barberis, D. Evolution of the Use of Relational and NoSQL Databases in the ATLAS Experiment / D.Barberis // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.962-968. - Bibliogr.:17.

 

188. Favareto, A. Use of the Hadoop Structures Storage Tools for the ATLAS EventIndex Event Catalogue / A.Favareto // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.974-979. - Bibliogr.:10.

 

189. Filozova, I.A. Concept of JINR Corporate Information System / I.A.Filozova, M.V.Bashashin, V.V.Korenkov, S.V.Kuniaev, G.Musulmanbekov, R.N.Semenov, G.V.Shestakova, T.A.Strizh, P.V.Ustenko, T.N.Zaikina // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.980-985. - Bibliogr.:5.

 

190. Furano, F. Dynamic Federation of Grid and Cloud Storage / F.Furano, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.986-992. - Bibliogr.:10.

 

191. Gertsenberger, K.V. The Unified Database for the Fixed Target Experiment BM@N / K.V.Gertsenberger // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.993-999. - Bibliogr.:4.

 

28.0 - Биология

192. Doostmohammadi, A. Defect-Mediated Morphologies in Growing Cell Colonies / A.Doostmohammadi, [et al.] // Physical Review Letters. – 2016. – Vol.117, No.4. – p.048102. - Bibliogr.:55.

http://dx.doi.org/10.1103/PhysRevLett.117.048102

28.08 - Экология

193. Cheremisina, E.N. New Technologies of 2D and 3D modeling for Analysis and Management of Natural Resources / E.N.Cheremisina, [et al.] // Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5. – p.1006-1009. - Bibliogr.:3.

 

СПИСОК ПРОСМОТРЕННЫХ ЖУРНАЛОВ


1. Cryogenics [Electronic Resource]. – 2016. – Vol.79. – Electronic journal. - Title from the title screen.

2. International Journal of Modern Physics B [Electronic resource]. – 2016. – Vol.30, No.19. – Electronic journal. - Title from the title screen.

3. International Journal of Modern Physics E [Electronic resource]. – 2016. – Vol.25, No.8. – Electronic journal. - Title from the title screen.

4. Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.5. – Electronic journal. - Title from the title screen.

5. Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.6. – Electronic journal. - Title from the title screen.

6. Journal of High Energy Physics [Electronic resource]. – 2016. – Vol.2016, No.7. – Electronic journal. - Title from the title screen.

7. Modern Physics Letters A [Electronic resource]. – 2016. – Vol.31, No.25. – Electronic journal. - Title from the title screen.

8. Nuclear Instruments & Methods in Physics Research A. – 2016. – Vol.829. – P.1-472.

9. Physical Review Letters. – 2016. – Vol.117, No.4. – P.040401-049901.

10. Physical Review Letters. – 2016. – Vol.117, No.5. – P.050401-059903.

11. Review of Scientific Instruments [Electronic resource]. – 2016. – Vol.87, No.8. – Electronic journal. - Titlt from the title screen.

12. Физика твердого тела. – 2016. – Т.58, №9. – С.1665-1872.

13. Физика элементарных частиц и атомного ядра. Письма. – 2016. – Т.13, №5.

14. Ядерная физика. – 2016. – Т.79, №5. – С.431-580.