| № | Title | Journal |
| 1. | Phase formation in ceramic materials that contain a cordierite glass synthesized by means of a large solar furnace | Applied Solar Energy 01/2013; 49(1). DOI:10.3103/S0003701X13010106 |
| 2. | Characteristics of phase formation in Angren deposit clays melted with a solar furnace | Applied Solar Energy 01/2014; 50(1):27-29. DOI:10.3103/S0003701X14010113
Renewable Energy Global Innovations {ISSN 2291-2460}, October 11, 2014 |
| 3. | Manufacture of Ceramic High-Porosity Cellular Materials Based on Raw Materials and Production Wastes in Uzbekistan | Glass and Ceramics 05/2015; 72(1-2):35-37.
DOI:10.1007/s10717-015-9718-2, 0.38 Impact Factor |
| 4. | Solar technologies in Uzbekistan: State, priorities, and perspectives of development | Applied Solar Energy 04/2012; 48(2). DOI:10.3103/S0003701X1202003X |
| 5. | Synthesis of calcium aluminates on the big solar furnace | Applied Solar Energy 04/2012; 48(2). DOI:10.3103/S0003701X12020041 |
| 6. | Results of actinometric measurements at location of LSF with thermal capacity of 1000 kW | Applied Solar Energy 07/2012; 48(3). DOI:10.3103/S0003701X12030024 |
| 7. | A system with a tracking concentrating heliostat for lighting underground spaces with beams of sunlight | Applied Solar Energy 04/2014; 50(2):122-124. DOI:10.3103/S0003701X14020030 |
| 8. | The optimization of the optical-geometric characteristics of mirror concentrating systems | Applied Solar Energy 10/2015; 50(4):244-251. DOI:10.3103/S0003701X14040033 |
| 9. | Optical-geometric parameters of a linear Fresnel mirror with flat facets | Applied Solar Energy. Volume 50, Issue 3, pp. 168-170 |
| 10. | Adjustment Of Facets Of Flat And Focusing Heliostats, Concentrators, And Fresnel Mirror Concentrating Systems. | Applied Solar Energy. v.51.pp,151-155. ИМПАКТ-фактор 0.16-0.2 SJR |
| 11. | The calculation procedure of the optical-energy characteristics of mirror concentrating systems for technological and energy application | Applied Solar Energy. Volume 51, Issue 4, pp 301-305. ИМПАКТ-фактор 0.16-0.2 SJR |
| 12. | Creation Of Impulses Of Concentrated Solar Radiation Of Different Capacity And Duration | Applied Solar Energy. v.51. pp, 148-150. ИМПАКТ-фактор 0.16-0.2 SJR |
| 13. | Antireflection textured coating for silicon solar cells | Applied Solar Energy, Volume 51, Issue 1, pp 83-84. ИМПАКТ-фактор 0.16-0.2 SJR |
| 14. | The Properties of Pyroceramic Materials Syntheses by Concentrated Solar Energy | International Journal of Mining Science (IJMS) Volume 1, issue 2, pp.1-5. ИМПАКТ-фактор 0.868 SJR |
| 15. | Особенности получения многофункциональной керамики на базе минерального сырья Узбекистана | Огнеупоры и техническая керамика №1-2, с.77-81. ИМПАКТ-фактор 0.25 SJR |
| 16. | Отличительные особенности керамогранита и естественного гранита | Огнеупоры и техническая керамика. – № 3. – С. 35-37. ИМПАКТ-фактор 0.25 SJR |
| 17. | Функциональная керамика, синтезированная в солнечной печи | Огнеупоры и техническая керамика. – № 3. – С. 42-47. ИМПАКТ-фактор 0.25 SJR |
| 18. | Manufacture of Ceramic High-Porosity Cellular Materials Based on Raw Materials and Production Wastes in Uzbekistan | Glass and Ceramics. Volume 72(1-2). pp. 35-37. Impact Factor: 0.65. |
| 19. | Basalt Fibers Obtained in a Solar Furnace | Glass and Ceramics. Volume 72, Issue 7, pp. 278-279. Impact Factor: 0.65. https://link.springer.com/journal/10717 |
| 20. | Solar technology for the synthesis and investigation of superconducting ceramics Bi1,7Pb0,3Sr2Ca(n-1)CunOy(n= 3÷5) | Refractories and Industrial Ceramics №1. pp 35-39. Impact Factor: 0.54 |
| 21. | Структурообразование в системе TiO2–BaСO3 в поле концентрированного солнечного излучения | Журнал Стекло и керамика. №3.ст.16-19. Impact Factor: 0.65 |
| 22. | Об изменении характеристик зонной структуры оксидных материалов при высоких температурах | Журнал «Теплофизика высоких температур», том 54, № 4, с. 1–7 |
| 23. | Analytical Approaches of Calculation of the Density Distribution of Radiant Flux from the Sun for Parabolic–Cylindrical Mirror-Concentrating Systems | Applied Solar Energy, Vol. 52, No. 2, pp. 137–140 |
| 24. | Method of Alignment of the Optical Axis of a Heliostat Tracking Sensor with the Main Optical Axis of the Concentrator | Applied Solar Energy, Vol. 52, No. 3, pp. 215–219. ИМПАКТ-фактор 0.25 SJR |
| 25. | On ensuring the plasticity of molding composition in the manufacture of ceramic catalyst carriers | Refractories and Industrial Ceramics. pp 21-26. Impact Factor: 0.54 |
| 26. | Improving dielectric properties of piezoelectric ceramics of concentrated solar radiation flux | Refractories and Industrial Ceramics. pp 34-37. Impact Factor: 0.54 |
| 27. | Определение эффективности фильтрации пенокерамических фильтров на основе сырьевых материалов и отходов производства Узбекистана | «Стекло и керамика». №4. ст.30-32. Impact Factor: 0.65 |
| 28. | Получение мелкокристаллического иттрий-алюминиевого граната в солнечных печах | Новые огнеупоры. №3,144-147 |
| 29. | Preparation of finely crystalline yttrium-aluminum garnet in solar furnaces | Refractories and Industrial Ceramics. Vol.58, No.2, р.179-182. Impact Factor: 0.54 |
| 30. | Эффективность очистки жидкостей от механических примесей при использовании керамических мембран | Огнеупоры и техническая керамика. №3. стр.24-28 |
| 31. | Calculation of optical-geometrical characteristics of parabolic-cylindrical mirror concentrating systems | «European science review» # 1-2, pp.28-32. Impact Factor: 1 |
| 32. | Measurements of Solar Resources in Uzbekistan | Applied Solar Energy, Vol. 1, pp. 57-60. ИМПАКТ-фактор 0.25 SJR |
| 33. | Глины Узбекистана как сырьевой материал для получения защитных покрытий на стальных поверхностях | “Огнеупоры и техническая керамика” – №1-2. – стр. 45-48. Impact Factor: 0.65 |
| 34. | Materials for Surface Protection of Heating Boiler Tubes | Glass and Ceramics. Volume 74, Issue 5–6, pp 172–175. Impact Factor: 0.65 |
| 35. | Химическая стойкость материалов на основе плавленого минерального сырья Узбекистана | Стекло и керамика. №7 – С.32-36. Impact Factor: 0.65 |
| 36. | Влияние термообработки на свойства жидкого стекла | Огнеупоры и техническая керамика. – №6 – С.44-50 |
| 37. | Обеспечение безопасности хранения серной кислоты | Computational nanotechnology, № 2. ст. 62-79 Impact Factor: 0.19 |
| 38. | Characteristic Features of the Energy Modes of a Large Solar Furnace with a Capacity of 1000 kW | Applied Solar Energy, 2018, Vol. 54, No. 2, pp. 99–109. ИМПАКТ-фактор 0.25 SJR |
| 39. | Optical-energy characteristics of the optimal module of a solar composite parabolic-cylindrical installation | Applied Solar Energy, 2018, Vol. 54, No. 4 .pp.43-48 |
| 40. | Modeling and Calculation of Optical-Geometric Characteristics of a Solar Concentrator with Flat Fresnel Mirrors | Applied Solar Energy, 2018, Vol. 54, No. 3, pp. 187–192 |
| 41. | O features of synthesis of functional ceramics with a complex of the set properties by a radiation method. Part 3 | Computational nanotechnology, 2-2018, 77-87. Impact Factor: 0.19 |
| 42. | Regressions models for forecasting of earthquakes | Computational nanotechnology, 2-2018, 43-46. Impact Factor: 0.19 |
- Р.Ю. АКБАРОВ, М.С. ПАЙЗУЛЛАХАНОВ, ХАРАКТЕРНЫЕ ОСОБЕННОСТИ ЭНЕРГЕТИЧЕСКИХ РЕЖИМОВ БОЛЬШОЙ СОЛНЕЧНОЙ ПЕЧИ МОЩНОСТЬЮ 1000 кВт
- R. AKBAROV, DOUBLE MIRROR HIGH-TEMPERATURE THOUSAND KW SOLAR FURNACE
- HIGH-TEMPERATURE SUPERCONDUCTORS OF THE Bi1.7Pb0.3Sr2Ca (n – 1) CunOy (n = 2–20) SERIES SYNTHESIZED UNDER THE INFLUENCE OF CONCENTRATED SOLAR ENERGY
- HIGHLY EFFECTIVE RESOURCE – SAVING TECHNOLOGIES OF WELDING MATERIALS FOR STRUCTURAL METALS AND ALLOYS
- OPTIMIZATION OF TECHNOLOGY FOR CREATION OF COMPOSITE ANTIREFLECTION COATINGS FOR SILICON SOLAR CELLS
- ANTIREFLECTIVE COATINGS FOR GLASS AND PLASTIC SUBSTRATES OF ORGANIC SOLAR CELLS