1.Авезов Р.Р., Вохидов А.У., Куралов М.А. Қуёш энергетикасининг Ўзбекистон Республикасида ривожлантириш тамойиллари.//Қайта тикланувчи энергетиканинг замонавий муаммолари. Республика илмий-амалий анжумани материаллари тўплами. Қарши. 18 март 2018й., 11-13 б.

2.Abdurakhmanov A., Kuchkarov A.A., Holov Sh. R., Abdumuminov A.Calculation of optical-geometrical characteristics of parabolic-cylindrical mirror concentrating systems // European science review. 2017. Vol. 2. P. 201-204.

3.Klychev Sh.I., Zakhidov R.A., Bakhramov S.A., Dudko Yu.A., Khudoikulov A.Ya., Klychev Z.Sh., and Khudoiberdiev I.A. Parameter optimization for paraboloid-cylinder-receiver system of thermal power plants // Applied Solar Energy. Applied Solar Energy. 2009. Vol. 45. No. 4. P. 281–284.

4.R.R. Avezov, N.R. Avezova, N.A. Matchanov, Sh.I. Suleimanov, R.D. Abdukadirova. History and State of Solar Engineering in Uzbekistan. Applied Solar Energy, 2012, Vol. 48, No. 1, pp. 14–19.

5.S. Morales, R. Miranda, D. Bustos, T. Cazares, H. Tran, Solar biomass pyrolysis for the production of bio-fuels and chemical commodities, J. Anal. Appl. Pyrolysis 109 (2014) 65-78.

6.M.H. Joardder, P.K. Halder, A. Rahim, N. Paul, Solar assisted fast pyrolysis: a novel approach of renewable energy production, J. Eng. 2014 (2014).

7.K. Zeng, D.P. Minh, D. Gauthier, E. Weiss-Hortala, A. Nzihou, G. Flamant, The effect of temperature and heating rate on char properties obtained from solar pyrolysis of beech wood, Bioresour. Technol. 182 (2015) 114-119.

8.J. Zeaiter, M.N. Ahmad, D. Rooney, B. Samneh, E. Shammas, Design of an automated solar concentrator for the pyrolysis of scrap rubber, Energy Convers. Manag. 101 (2015) 118-125.

9.Szymon Sobek, SebastianWerle. Solar pyrolysis of waste biomass: Part 1 reactor design. Renewable Energy. Volume 143, December 2019, Pages 1939-1948.

10.Venkateswarlu Chintala. Production, upgradation and utilization of solar assisted pyrolysis fuels from biomass – A technical review. Renewable and Sustainable Energy Reviews 90 (2018) pages 120–130.

11.Kuo Zeng, Rui Li, Doan Pham Minh, Elsa Weiss-Hortala, Ange Nzihou, Xiao He. Solar pyrolysis of heavy metal contaminated biomass for gas fuel production. Energy 187 (2019) 116016.

12.Grassmann, H., Boaro, M., Citossi, M., Cobal, M., Эrsettis, E., Kapllaj, E., Pizzariello, A., 2015. Solar biomass pyrolysis with the linear mirror II. Smart Grid Renew. Energy 6, 179–186.

13.Ayala-Cortés A., Arancibia-Bulnes C.A., Villafán-Vidales H.I., Lobato-Peralta D.R., Martinez-Casillas D., Cuentas-Gallegos A.K. Solar pyrolysis of agave and tomato pruning wastes: insights of the effect of pyrolysis operation parameters on the physicochemical properties of biochar. In: A Paper Presented at the SolarPACES Conference in Morocco, 2018.

14.Li, R., Zeng, K., Soria, J.E., Mazza, G.A., Gauthier, D., Rodriguez, R., Flamant, G. Product distribution from solar pyrolysis of agricultural and forestry biomass residues. Renew. Energy 89, 27–35.

15.Beagle, E., 2012. Fast Pyrolysis of Biomass using Concentrated Solar Radiation. In: A Presentation to School of Energy Resources, University of Wyoming.

16.Yingpu Xie, Kuo Zeng. Solar pyrolysis of cotton stalk in molten salt for bio-fuel production. Energy 179 (2019) pages 1124-1132.

17.Sanchez, B. Clifford, J.D. Nixon. Modelling and evaluating a solar pyrolysis system. Renewable Energy, 116 (2018), pages 630-638.

18.M. Pfänder, E. Lüpfert, P. Heller, Pyrometric temperature mesurements on solar thermal high temperature receivers, J. Sol. Energy – T ASME 128 (2006) 285–292.

19.A. Luzzi, K. Lovegrove, Solar Thermal Power Generation, Australian National University, Camberra, 2004, pp. 669–683.

20.Nzihou, A., Flamant, G., Stanmore, B., 2012. Synthetic fuels from biomass using concentrated solar energy - a review. Energy 42, 121–131.

21.Хутская Н.Г., Г.И. Пальчёнок. Энергосберегающие технологии термохимической конверсии биомассы и лигнокарбонатных отходов: учебно-методическое пособие. Минск: БНТУ, 2014. - 53 с.

22.Ғ.Н.Узоқов, Х.А.Давлонов. Гелиоиссиқхоналарнинг энергия тежамкор иситиш тизимлари // Монография. Тошкент, Ворис-нашриёти, 143 б.

23.Uzakov, G.N., Davlonov, H.A., Holikov, K.N. Study of the Influence of the Source Biomass Moisture Content on Pyrolysis Parameters. Applied Solar Energy (English translation of Geliotekhnika), 2018, Том 54, Выпуск 6, Pages 481 – 484.

24.Х.А Алмарданов, И.А. Хатамов, З.Б. Тураев, Р.Э. Юсупов. Применение солнечных концентраторов для приема альтернативного топлива через устройство гелиопиролиза. Universum: технические науки, 2021, 8-12 ст. № 4 (85) апрель, 2021 г.

25.Ш.Б. Имомов, Х.А. Алимардонов. Heat mode solar heating systems based on flat reflectors, sets on the north side of the building. Молодой ученый, 2015, 335-336 ст.

26.К.К. Рахимова, Х.А. Алмарданов, С.И. Хамраев, С.М. Шамуратова, А.Р. Тошбоев, Э.Э. Турдиев. Теплоснабжение и энергосбережение сельскохозяйственных сооружений с пассивной системой солнечного отопления. ГГТУ им. ПО Сухого, 2020, 242-245 ст.

27.Т.Я. Хамраев, Х.А. Алмарданов. Режим работы установок для получения биогаза из сельскохозяйственных отходов. Молодой ученый. — 2020. — № 25 (315). — С. 49-52.

28.Davlonov X.A., Almardanov H.A., Toshboyev A.R., Umirov F.B. Method of Thermal Processing of Biomass With Heliopyrolysis Device. 2021, International Journal of Human Computing Studies, 3(2), 149-151.

29.Х.А. Алмарданов, А.В. Новик, С.Э. Чулиев. Тепловой расчет гелиопиролизного устройства концентратора. БНТУ, 2022, 187-192 ст.

30.авлонов Х. А., Алмарданов Х. А. Исследование теплового режима процесса гелиопиролиза биомасса //Universum: технические науки. – 2021. – №. 4-5 (85). – С. 5-8.

Green T, Miria OI, Crook R, Ross A. Energy Calculator for Solar Processing of Biomass with Application to Uganda. Energies. 2020; 13(6):1485. https://doi.org/10.3390/en13061485.

32.Funke, A.; Ziegler, F. Heat of reaction measurements for hydrothermal carbonization of biomass. Bioresour. Technol. 2011, 102, 7595–7598. [CrossRef] [PubMed].

33.Daugaard, D.E.; Brown, R.C. Enthalpy for Pyrolysis for Several Types of Biomass. Energy Fuels 2003, 17, 934–939. [CrossRef].