DANH MỤC CÁC CÔNG TRÌNH ĐÃ CÔNG BỐ Nguyễn Khánh Diệu Hồng, Nguyễn Đăng Toàn, Nguyễn Trung Thành, Lê Thị Hồng Ngân, Đinh Thị Ngọ (2012) Xác định tiêu kỹ thuật phân tích thành phần hóa học dầu vi tảo họ Botryococcus sp làm nguyên liệu cho sản xuất biodiesel Tạp chí Hóa học số 50(4A), trang 375-378 Đinh Thị Ngọ, Nguyễn Đăng Toàn, Nguyễn Trung Thành, Nguyễn Lệ Tố Nga (2013) Nghiên cứu chuyển hóa sinh khối vi tảo thành nhiên liệu sinh học biodiesel Hội nghị Trí tuệ dầu khí Việt Nam - Hội nhập phát triển bền vững – Hà Nội Tháng 5/2013, trang 679-686 Nguyễn Trung Thành, Đinh Thị Ngọ (2013) Nghiên cứu chế tạo xúc tác SO4 2/ZrO2 ứng dụng cho phản ứng este hóa dầu vi tảo Tạp chí hóa học số 51(4AB), trang 187192 Nguyễn Trung Thành, Lê Quang Diễn, Nguyễn Thế Hào, Đinh Thị Ngọ (2013), Nghiên cứu chế tạo xúc tác Ca(NO3)2/SiO2, ứng dụng cho phản ứng giai đoạn hai trình tổng hợp biodiesel từ nguyên liệu dầu vi tảo Tạp chí Hóa học số 51(6ABC), trang 399-404 Nguyễn Khánh Diệu Hồng, Nguyễn Đăng Toàn, Nguyễn Trung Thành, Bùi Trọng Quý, Nguyễn Thị Hà, Vũ Đình Duy (2014) Nghiên cứu phụ thuộc hiệu suất tạo metyl ester vào độ nhớt hỗ hợp sản phẩm phản ứng tổng hợp metyl ester từ số loại nguyên liệu điển hình Tạp chí dầu khí số 4/2014, trang 50-59 Nguyen Dang Toan, Nguyen Khanh Dieu Hong, Nguyen Trung Thanh, Nguyen Thi Ha (2014) Studying on the Relation Between Conversion and Product Viscosity in Methanolysis from Various ISEPD 2014, Hanoi, vietnam, pp 154-158 Nguyễn Trung Thành, Nguyễn Khánh Diệu Hồng, Đinh Thị Ngọ (2014) Nghiên cứu tổng hợp biodiesel từ nguyên liệu dầu vi tảo trình hai giai đoạn sử dụng hệ xúc tác axit – bazơ rắn Tạp chí Hóa học số 52(4), trang 484-489 Nguyễn Trung Thành, Nguyễn Đăng Toàn, Đinh Thị Ngọ (2015) Nghiên cứu chiết tách dầu từ sinh khối vi tảo họ Botryococcus sp làm nguyên liệu cho trình tổng hợp Biodiesel Tạp chí Khoa học Công nghệ số 53(3), trang 646-653 107 TÀI LIỆU THAM KHẢO [1] Bùi Đình Lãm, Đinh Thị Ngọc Mai, Lê Thị Thơm, Đoàn Lan Phương, Đặng Diễm Hồng (2013), Sản xuất diesel sinh học từ vi tảo Chloerella sp phương pháp chuyển vị ester chỗ Tạp chí Công nghệ Sinh học, 33(4), pp 66-71 [2] Đặng Diễm Hồng, Hoàng Thị Lan Anh, Nguyễn Thị Minh Thanh (2009), Tách chiết tinh acid béo không bão hoà từ sinh khối vi tảo biển dị dưỡng Schizochytrium mangrrovei PQ6 Tạp chí Công nghệ Sinh học, 7(3), pp 381-387 [3] Lê Thị Thơm, Đinh Thị Ngọc Mai, Đinh Đức Hoàng, Bùi Đình Lãm, Nguyễn Cẩm Hà, Đặng Diễm Hồng (2012), Nghiên cứu áp dụng phương pháp chuyển vị ester chỗ để sản xuất diesel sinh học từ vi tảo biển Nannochloropsis oculata Tạp chí Công nghệ Sinh học, 10 (2), pp 331-337 [4] Ngô Thị Hoài Thu, Nguyễn Thị Minh Thanh, Hoàng Thị Lan Anh, Đinh Thị Thu Hằng, Đặng Diễm Hồng (2010), Sàng lọc loài vi tảo biển quang tự dưỡng làm nguyên liệu cho sản xuất diesel sinh học Tạp chí Khoa học Công nghệ, 48(4A), pp 320-325 [5] Nguyễn Khánh Diệu Hồng, Đinh Thị Ngọ (2012), Nhiên Liệu trình xử lý hóa dầu Nhà xuất Khoa Học Kĩ Thuật [6] Trương Vĩnh (2011), Nghiên cứu quy trình công nghệ sản xuất biodiesel từ vi tảo Việt Nam Đề tài cấp mã số B2008 – 12 – 66 [7] A Catarina Guedes, Helena M Amaro, Catarina R Barbosa, Ricardo D Pereira and F Xavier Malcata (2011), Fatty acid composition of several wild microalgae and cyanobacteria, with a focus on eicosapentaenoic, docosahexaenoic and α-linolenic acids for eventual dietary uses Food research international, 44(9), pp 2721-2729 [8] A Kumudha C Dayananda, R Sarada and G A Ravishankar (2010), Isolation, characterization and outdoor cultivation of green microalgae Botryococcus sp Scientific Research and Essays, 7(17), pp 2497-2505 [9] A L Ahmad, N H Mat Yasin, C J C Derek and J K Lim (2011), Microalgae as a sustainable energy source for biodiesel production: A review Renewable and Sustainable Energy Reviews, 15(1), pp 584-593 [10] AK Azad, MG Rasul, Mohammad Masud Kamal Khan and Subhash C Sharma (2014) Review of biodiesel production from microalgae: a novel source of green energy The 9th International Green Energy Conference, Tianjin, China [11] Ali Alsalme, Elena F Kozhevnikova and Ivan V Kozhevnikov (2008), Heteropoly acids as catalysts for liquid-phase esterification and transesterification Applied Catalysis A: General, 349(1), pp 170-176 108 [12] Aline Terra Soares, Dayane Cristine da Costa, Bruna Ferreira Silva, Rafael Garcia Lopes, Roberto Bianchini Derner and Nelson Roberto Antoniosi Filho (2014), Comparative analysis of the fatty acid composition of microalgae obtained by different oil extraction methods and direct biomass transesterification BioEnergy Research, 7(3), pp 10351044 [13] Anjana Srivastava and Ram Prasad (2000), Triglycerides-based diesel fuels Renewable and sustainable energy reviews, 4(2), pp 111-133 [14] Antonio A Teresa and M Mata (2010), Martins Microalgae for biodiesel production and other applications: A review Renewable and Sustainable Energy Reviews, 14, pp 217232 [15] Arumugam Sivasamy, Kien Yoo Cheah, Paolo Fornasiero, Francis Kemausuor, Sergey Zinoviev and Stanislav Miertus (2009), Catalytic applications in the production of biodiesel from vegetable oils ChemSusChem, 2(4), pp 278-300 [16] Ayhan Demirbas (2008), A Realistic Fuel Alternative for Diesel Engines Springer [17] Ayhan Demirbas (2008), Biofuels sources, biofuel policy, biofuel economy and global biofuel projections Energy conversion and management, 49(8), pp 2106-2116 [18] Ayhan Demirbas and M Fatih Demirbas (2010), Algae energy: algae as a new source of biodiesel Springer [19] Benjaram M Reddy, Pavani M Sreekanth and Pandian Lakshmanan (2005), Sulfated zirconia as an efficient catalyst for organic synthesis and transformation reactions Journal of molecular catalysis A: chemical, 237(1), pp 93-100 [20] Benoit Heinrichs, Stéphanie Lambert, Nathalie Job and Jean-Paul Pirard (2006), SolGel synthesis of supported metals Catalyst Preparation: Science and Engineering, ed J Regalbuto, Tayler & Francis (CRC Press), Boca Raton, pp 163 [21] C Dayananda, A Kumudha, R Sarada and GA Ravishankar (2010), Isolation, characterization and outdoor cultivation of green microalgae Botryococcus sp Sci Res Essays, 5(17), pp 2497-2505 [22] Camila Martins Garcia, Sergio Teixeira, Letícia Ledo Marciniuk and Ulf Schuchardt (2008), Transesterification of soybean oil catalyzed by sulfated zirconia Bioresource technology, 99(14), pp 6608-6613 [23] Chang-Lin Chen, Tao Li, Soofin Cheng, Hong-Pin Lin, Chetan J Bhongale and Chung-Yuan Mou (2001), Direct impregnation method for preparing sulfated zirconia supported on mesoporous silica Microporous and mesoporous materials, 50(2), pp 201208 [24] Chawalit Ngamcharussrivichai, Sita Benjapornkulaphong and Kunchana Bunyakiat 109 (2009), Al2O3-supported alkali and alkali earth metal oxides for transesterification of palm kernel oil and coconut oil Chemical Engineering Journal, 145(3), pp 468-474 [25] Chiara Samorì, Cristian Torri, Giulia Samorì, Daniele Fabbri, Paola Galletti, Franca Guerrini, Rossella Pistocchi and Emilio Tagliavini (2010), Extraction of hydrocarbons from microalga Botryococcus braunii with switchable solvents Bioresource technology, 101(9), pp 3274-3279 [26] D Farcasu and J Q Li (1995), Preparation of sulfated zirconia catalysts with improved control of sulfur content Applied Catalysis A: General, 128(1), pp 97-105 [27] Dae-Won Lee, Young-Moo Park and Kwan-Young Lee (2009), Heterogeneous base catalysts for transesterification in biodiesel synthesis Catalysis surveys from Asia, 13(2), pp 63-77 [28] Dang Diem Hong, Dinh Thi Ngoc Mai, Le Thi Thom, Nguyen Cam Ha, Bui Dinh Lam, Luu Thi Tam, Hoang Thi Lan Anh and Ngo Thi Hoai Thu (2013), Biodiesel production from Vietnam heterotrophic marine microalga Schizochytrium mangrovei PQ6 Journal of Bioscience and Bioengineering, 116(2), pp 180-185 [29] Daniel G Strawn, Hinrich L Bohn and George A O'Connor (2015), Soil Chemistry John Wiley & Sons [30] David Adam (2008), World CO2 levels at record high, scientists warm The Guardian, 12, pp [31] David M bagley Jerald A.Lalman (2004), Extracting Long-Chain Fatty Acids from a Fermentation Medium Journal of the American Oil Chemists' Society, 81(2), pp 105110 [32] Demirbas A (2011), Methylation of wood fatty and resin acids for production of biodiesel Fuel, 90, pp 2273–2281 [33] Dominik Rutz and Rainer Janssen (2007), Biofuel technology handbook WIP Renewable Energies, Sylvensteinstr 2, Munich, Germany [34] E Sánchez, K Ojeda, M El-Halwagi and V Kafarov (2011), Biodiesel from microalgae oil production in two sequential esterification/transesterification reactors: Pinch analysis of heat integration Chemical Engineering Journal, 176-177, pp 211-216 [35] Edgar Lotero, Yijun Liu, Dora E Lopez, Kaewta Suwannakarn, David A Bruce and James G Goodwin (2005), Synthesis of biodiesel via acid catalysis Industrial & engineering chemistry research, 44(14), pp 5353-5363 [36] Ela Eroglu and Anastasios Melis (2010), Extracellular terpenoid hydrocarbon extraction and quantitation from the green microalgae Botryococcus braunii var Showa Bioresource technology, 101(7), pp 2359-2366 110 [37] Folasegun A Dawodu, Olubunmi Ayodele, Jiayu Xin, Suojiang Zhang and Dongxia Yan (2014), Effective conversion of non-edible oil with high free fatty acid into biodiesel by sulphonated carbon catalyst Applied Energy, 114, pp 819-826 [38] Fred R Wolf, Arthur M Nonomura and James A Bassham (1985), Growth and branched hydrocarbon production in a strain of Botryococcus braunii (chlorophyta) Journal of Phycology, 21(3), pp 388-396 [39] Geoffrey Brooks (2010), Edible oil and processes for its production from microalgae United States patent application publication, Publication number US20100303957 A1 [40] Gerhard Knothe, Jon Harlan Van Gerpen and Jurgen Krahl (2005), The biodiesel handbook Vol 1, AOCS press Champaign, IL [41] Geun Ho Gim, Jung Kon Kim, Hyeon Seok Kim, Mathur Nadarajan Kathiravan, Hetong Yang, Sang-Hwa Jeong and Si Wouk Kim (2014), Comparison of biomass production and total lipid content of freshwater green microalgae cultivated under various culture conditions Bioprocess and biosystems engineering, 37(2), pp 99-106 [42] Gisela Monter and Margarita Stoytcheva (2011), Biodiesel – Quality, emissions and by-products Intech open Publisher [43] Gisela Montero Margarita Stoytcheva (2011), Biodiesel - Feedstocks and Processing Technologies Janeza Trdine 9, 51000 Rijeka, Croatia [44] GuanHua Huang, Feng Chen, Dong Wei, XueWu Zhang and Gu Chen (2010), Biodiesel production by microalgal biotechnology Applied Energy, 87(1), pp 38-46 [45] H Knozinger G Ertl, J Weitkamp (1997), Handbook of Heterogeneous Catalysis Vol 5, Wiley-VCH, Weinheim [46] Hideshi Hattori (1995), Heterogeneous basic catalysis Chemical Reviews, 95(3), pp 537-558 [47] Hu Qunju, Xiang Wenzhou, Dai Shikun, Li Tao, Yang Fangfang, Jia Qikun, Wang Guanghua and Wu Hualian (2015), The influence of cultivation period on growth and biodiesel properties of microalgae Nannochloropsis gaditana 1049 Bioresource Technology [48] International Energy Agency (2004), World Energy Outlook pp 57 [49] Izabela Krzemińska, Barbara Pawlik-Skowrońska, Magdalena Trzcińska and Jerzy Tys (2014), Influence of photoperiods on the growth rate and biomass productivity of green microalgae Bioprocess and biosystems engineering, 37(4), pp 735-741 [50] J.M Pareta and J.C Yori (1996), n - butane isomerization on metal promoted sulfated zirconia Appl Catal., A: General, 146, pp 332 111 [51] Jack A Sacco and Fabian E Dumont (2009), Biochemical Engineering Nova Science Publisher [52] James R.Oyler (2008), Two stage process for producing oil from microalgae United States patent application publication [53] Jasvinder Singh and Sai Gu (2010), Commercialization potential of microalgae for biofuels production Renewable and Sustainable Energy Reviews, 14(9), pp 2596-2610 [54] Jie Sheng, Raveender Vannela and Bruce E Rittmann (2011), Evaluation of methods to extract and quantify lipids from Synechocystis PCC 6803 Bioresource technology, 102(2), pp 1697-1703 [55] Jong Rack Sohn, Tae-Dong Kwon and Sang-Bock Kim (2001), Characterization of zirconium sulfate supported on zirconia and activity for acid catalysis BULLETINKOREAN CHEMICAL SOCIETY, 22(12), pp 1309-1315 [56] Juliana E Bohnenberger and Luciane O Crossetti (2014), Influence of temperature and nutrient content on lipid production in freshwater microalgae cultures Anais da Academia Brasileira de Ciências, 86(3), pp 1239-1248 [57] K Parkavi and B Mathumitha (2011), Review of key research efforts to make algae fuels sustainable ASTM Special Technical Publication, 1477, pp 566-576 [58] K Saravanan, Beena Tyagi, Ram S Shukla and HC Bajaj (2015), Esterification of palmitic acid with methanol over template-assisted mesoporous sulfated zirconia solid acid catalyst Applied Catalysis B: Environmental, 172, pp 108-115 [59] K Tanabe, Imelik B, Condurier G, BenTaarti Y, Vedrine J.C (1985), Catalysis by acids and bases Elsevier Amsterdam, pp 111-115 [60] Kazushi Arata (1996), Preparation of superacids by metal oxides for reaction of butanes and pentanes Applied Catalysis A: General, 146(1), pp 3-32 [61] Kenichiro Tsukahara and Shigeki Sawayama (2005), Liquid fuel production using microalgae J Jpn Pet Inst, 48(5), pp 251 [62] Kiyotaka Saga Sueko Atobe, Fumio Hasegawa , Akinari Magota, Kenichi Furuhashi, Shigeru Okada, Toru Suzuki and Kenji Imou (2014), The effect of the water-soluble polymer released from Botryococcus braunii Showa strain on solvent extraction of hydrocarbon Journal of Applied Phycology, 27(2), pp 755-761 [63] Kiyotaka Saga, Fumio Hasegawa, Syoko Miyagi, Sueko Atobe, Shigeru Okada, Kenji Imou, Noriko Osaka and Tetsu Yamagishi (2015), Comparative evaluation of wet and dry processes for recovering hydrocarbon from Botryococcus Braunii Applied Energy, 141, pp 90-95 112 [64] Kondo A Fukuda H, Noda H (2001), Biodiesel fuel production by transesterification of oils Journal of Bioscience and Bioengineering, 92, pp 405-420 [65], L Zhu Y.Y Sun, Feng-Shou Xiao (2005), Ordered Mesoporous Materials with Improved Stability and Catalytic Activity Topics in Catalysis, 35(1-2), pp 9-24 [66] Leonard Wagner (2007), Biodiesel from algae oil Research report [67] Liam Brennan and Philip Owende (2010), Biofuels from microalgae—a review of technologies for production, processing, and extractions of biofuels and co-products Renewable and sustainable energy reviews, 14(2), pp 557-577 [68] Lin Chen, Tianzhong Liu, Wei Zhang, Xiaolin Chen and Junfeng Wang (2012), Biodiesel production from algae oil high in free fatty acids by two-step catalytic conversion Bioresource Technology, 111(0), pp 208-214 [69] Lina Zhao (2010), Novel solid base catalysts for the production of biodiesel from lipids University of Kansas [70] M Canakci and J Van Gerpen (2001), Biodiesel production from oils and fats with high free fatty acids Transactions-American Society of Agricultural Engineers, 44(6), pp 1429-1436 [71] M.E Leonowicz C.T Kresge, J.C Vartuli and J.S Beck (1992), Ordered mesoporous molecular sieves synthesized by a liquid-crystal template mechanism Nature, 359, pp 710712 [72] M.Fatih Demirbas and Ayhan Demirbas (2010), Algae Energy Algae as a New Source of Biodiesel Springer Verlag London [73] M.R.M Adam P Harvey and Thomas Seliger (2003), Process Intensification Of Biodiesel Production Using A Continuous Oscillatory Flow Reactor Journal Of Chemical Technology And Biotechnology, 78, pp 338-341 [74] Marc Petit and Julien Monot (2015), Functionalization of Zirconium Oxide Surfaces Chemistry of Organo-Hybrids: Synthesis and Characterization of Functional NanoObjects, pp 168-199 [75] María Jesús Ramos, Abraham Casas, Lourdes Rodríguez, Rubí Romero and Ángel Pérez (2008), Transesterification of sunflower oil over zeolites using different metal loading: a case of leaching and agglomeration studies Applied Catalysis A: General, 346(1), pp 79-85 [76] Masato Kouzu, Takekazu Kasuno, Masahiko Tajika, Yoshikazu Sugimoto, Shinya Yamanaka and Jusuke Hidaka (2008), Calcium oxide as a solid base catalyst for transesterification of soybean oil and its application to biodiesel production Fuel, 87(12), 113 pp 2798-2806 [77] Minh Hien Hoang, Nguyen Cam Ha, Luu Thi Tam, Hoang Thi Lan Anh, Ngo Thi Hoai Thu and Dang Diem Hong (2014), Extraction of squalene as value-added product from the residual biomass of Schizochytrium mangrovei PQ6 during biodiesel producing process Journal of bioscience and bioengineering, 118(6), pp 632-639 [78] Mônica CG Albuquerque, Inmaculada Jiménez-Urbistondo, José SantamaríaGonzález, Josefa M Mérida-Robles, Ramón Moreno-Tost, Enrique Rodríguez-Castellón, Antonio Jiménez-López, Diana Azevedo, Célio L Cavalcante Jr and Pedro MairelesTorres (2008), CaO supported on mesoporous silicas as basic catalysts for transesterification reactions Applied Catalysis A: General, 334(1), pp 35-43 [79] Naeeda Tharakan, Jane Romero and David Morgado (2012), Biofuels in the Greater Mekong Subregion: Energy sufficiency, food security, and environmental management [80] Navid Moheimani (2014), Microalgae Culture (3) Algae R&D Center, Murdoch University, Perth, Australia [81] Nguyen Dang Toan, Nguyen Khanh Dieu Hong, Nguyen Trung Thanh and Nguyen Thi Ha Studying on the Relation Between Conversion and Product Viscosity in Methanolysis from Various ISEPD 2014, Hanoi, Vietnam, pp 154-158 [82] Oilgae comprehensive report: Energy from algae: product, Market, processes and strategies (2011) Oilgae magazine [83] P Mongkolbovornkij, V Champreda, W Sutthisripok and N Laosiripojana (2010), Esterification of industrial-grade palm fatty acid distillate over modified ZrO2 (with WO3, SO4 2and TiO2): Effects of co-solvent adding and water removal Fuel Processing Technology, 91(11), pp 1510-1516 [84] Palligarnai T Vasudevan and Michael Briggs (2008), Biodiesel production—current state of the art and challenges Journal of Industrial Microbiology & Biotechnology, 35(5), pp 421-430 [85] Persistence Team (2008), Annual 100,000T Biodiesel Production Project College of Materials Science and Chemical Engineering Zhejiang University [86] Piyushi Nautiyal, K A Subramanian and M G Dastidar (2014), Production and characterization of biodiesel from algae Fuel Processing Technology, 120(0), pp 79-88 [87] Ramasamy Rengasamy, Veeramuthu Ashokkumar, S Deepalakshmi, A Sivalingam and Pandian Sivakumar (2014), Mass cultivation of microalgae and extraction of total hydrocarbons: A kinetic and thermodynamic study Fuel, 119, pp 308-312 [88] Rashmi Shakeel A Khan and Z Hussain (2009), Prospects of biodiesel production from microalgae in India Renewable and Sustainable Energy Reviews, 13(9), pp 2361114 2372 [89] Raveender Vannela, Jie Sheng and Bruce E.Rittmann (2011), Evaluation of methods to extract and quantify lipids from Synchocystis Bioresource Technology, 102(2), pp 16971703 [90] RN Patil and EC Subbarao (1970), Monoclinic–tetragonal phase transition in zirconia: mechanism, pretransformation and coexistence Acta Crystallographica Section A: Crystal Physics, Diffraction, Theoretical and General Crystallography, 26(5), pp 535542 [91] Ronald Halim, Brendan Gladman, Michael K Danquah and Paul A Webley (2011), Oil extraction from microalgae for biodiesel production Bioresource Technology, 102(1), pp 178-185 [92] Ronald Halim, Michael K Danquah and Paul A Webley (2012), Extraction of oil from microalgae for biodiesel production: A review Biotechnology Advances, 30(3), pp 709-732 [93] S Semwal, A K Arora, R P Badoni and D K Tuli (2011), Biodiesel production using heterogeneous catalysts Bioresource Technology, 102(3), pp 2151-2161 [94] Satoshi Furuta, Hiromi Matsuhashi and Kazushi Arata (2004), Biodiesel fuel production with solid superacid catalysis in fixed bed reactor under atmospheric pressure Catalysis communications, 5(12), pp 721-723 [95] Shu-Hui Guan, Xiao-Jie Zhang and Zhi-Pan Liu (2015), Energy Landscape of Zirconia Phase Transitions Journal of the American Chemical Society, 137(25), pp 80108013 [96] Siti Zullaikah, Chao-Chin Lai, Shaik Ramjan Vali and Yi-Hsu Ju (2005), A two-step acid-catalyzed process for the production of biodiesel from rice bran oil Bioresource Technology, 96(17), pp 1889-1896 [97] T Brigitte Voit (2006), Sequential One-Pot eactions Using the Concept of ―Site Isolation‖ Angewandte Chemie International Edition, 45(26), pp 4238-4240 [98] T Groger H (2001), The development of new monometallic bifunctional catalysts with lewis acid and lewis base properties, and their application in asymmetric cyanation reactions Chemistry - A European Journal, 7(24), pp 4238-4240 [99] TG Volova, GS Kalacheva and NO Zhila (2003), Specificity of lipid composition in two Botryococcus strains, the producers of liquid hydrocarbons Russian Journal of Plant Physiology, 50(5), pp 627-633 [100] Torri C Samorì C, Samorì G, Fabbri D, Galletti P, Guerrini F, Pistocchi R and Tagliavini E (2010), Extraction of hydrocarbons from microalga Botryococcus braunii 115 with switchable solvents Bioresource Technology, 101(19), pp 3274-3279 [101] V Fornes A Corma, M.I.Juan-Rajadell and J.M.Lopez Nieto (1994), "Influence of preparation conditions on the structure and catalytic properties of ZrO2/SO42- superacid catalysts Applied Catalysis A: General, 116, pp 151-156 [102] Veeramuthu Ashokkumar, Ramasamy Rengasamy, S Deepalakshmi, A Sivalingam and Pandian Sivakumar (2014), Mass cultivation of microalgae and extraction of total hydrocarbons: A kinetic and thermodynamic study Fuel, 119, pp 308-312 [103] Venu Babu Borugadda and Vaibhav V Goud (2012), Biodiesel production from renewable feedstocks: Status and opportunities Renewable and Sustainable Energy Reviews, 16(7), pp 4763-4784 [104] Waqas Khatri, Robert Hendrix, Tom Niehaus, Joe Chappell and Wayne R Curtis (2014), Hydrocarbon production in high density Botryococcus braunii race B continuous culture Biotechnology and bioengineering, 111(3), pp 493-503 [105] Wenlei Xie and Haitao Li (2006), Alumina-supported potassium iodide as a heterogeneous catalyst for biodiesel production from soybean oil Journal of Molecular Catalysis A: Chemical, 255(1-2), pp 1-9 [106] Wenlei Xie and Xiaoming Huang (2006), Synthesis of biodiesel from soybean oil using heterogeneous KF/ZnO catalyst Catalysis Letters, 107(1-2), pp 53-59 [107] Wenlei Xie and Zhenqiang Yang (2007), Ba–ZnO catalysts for soybean oil transesterification Catalysis Letters, 117(3-4), pp 159-165 [108] Wenlei Xie, Hong Peng and Ligong Chen (2006), Transesterification of soybean oil catalyzed by potassium loaded on alumina as a solid-base catalyst Applied Catalysis A: General, 300(1), pp 67-74 [109] Xiaoming Huang, Wenlei Xie and Haitao Li (2007), Soybean oil methyl esters preparation using NaX zeolites loaded with KOH as a heterogeneous catalyst Bioresource Technology, 98, pp 936-939 [110] Xiufeng Li, Han Xu and Qingyu Wu (2007), Large‐scale biodiesel production from microalga Chlorella protothecoides through heterotrophic cultivation in bioreactors Biotechnology and Bioengineering, 98(4), pp 764-771 [111] YA Yi, JS Ahn, YJ Park, SH Jun, IB Lee, BH Cho, HH Son and DG Seo (2015), The effect of sandblasting and different primers on shear bond strength between yttriatetragonal zirconia polycrystal ceramic and a self-adhesive resin cement Operative dentistry, 40(1), pp 63-71 [112] Yahaya Muhammad Sani, Wan Mohd Ashri Wan Daud and A R Abdul Aziz (2013), Solid acid-catalyzed biodiesel production from microalgal oil—The dual 116 advantage Journal of Environmental Chemical Engineering, 1(3), pp 113-121 [113] Yahaya Muhammad Sani, Wan Mohd, Ashri Wan Daud and A R Abdul Aziz (2014), Activity of solid acid catalysts for biodiesel production: A critical review Applied Catalysis A: General, 470, pp 140-161 [114] Yusuf Chisti (2007), Biodiesel from microalgae Biotechnology Advances, 25(3), pp 294-306 [115] Zeidan R K T, Margelefsky E L and Davis M E (2008), Cooperative catalysis by silica-supported organic functional groups Chemical Society Reviews, 37(6), pp 11181126 [116] Zhonglai Li, Yichen Liu, Witold Kwapinski and James J Leahy (2014), ZrO 2modified TiO nanorod composite: Hydrothermal synthesis, characterization and application in esterification of organic acid Materials Chemistry and Physics, 145(1), pp 82-89 [117] Z.W David Vaughan (1975), Crystalline silica compositions United States patent application publication, Publication number 3884835 114 PHỤ LỤC Phụ lục 1: Kết đo BET 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 Phụ lục Kết GS-MS 133 134 135 136 137 PHỤ LỤC Kết TPD-NH3 138 139 140 141 142 143 144 145 146 147 Phụ lục Kết chụp XRD [...]... Solid acid-catalyzed biodiesel production from microalgal oil—The dual 116 advantage Journal of Environmental Chemical Engineering, 1(3), pp 113-121 [113] Yahaya Muhammad Sani, Wan Mohd, Ashri Wan Daud and A R Abdul Aziz (2014), Activity of solid acid catalysts for biodiesel production: A critical review Applied Catalysis A: General, 470, pp 140-161 [114] Yusuf Chisti (2007), Biodiesel from microalgae... Physics, Diffraction, Theoretical and General Crystallography, 26(5), pp 535542 [91] Ronald Halim, Brendan Gladman, Michael K Danquah and Paul A Webley (2011), Oil extraction from microalgae for biodiesel production Bioresource Technology, 102(1), pp 178-185 [92] Ronald Halim, Michael K Danquah and Paul A Webley (2012), Extraction of oil from microalgae for biodiesel production: A review Biotechnology... (2012), Biodiesel production from renewable feedstocks: Status and opportunities Renewable and Sustainable Energy Reviews, 16(7), pp 4763-4784 [104] Waqas Khatri, Robert Hendrix, Tom Niehaus, Joe Chappell and Wayne R Curtis (2014), Hydrocarbon production in high density Botryococcus braunii race B continuous culture Biotechnology and bioengineering, 111(3), pp 493-503 [105] Wenlei Xie and Haitao Li... Jane Romero and David Morgado (2012), Biofuels in the Greater Mekong Subregion: Energy sufficiency, food security, and environmental management [80] Navid Moheimani (2014), Microalgae Culture (3) Algae R&D Center, Murdoch University, Perth, Australia [81] Nguyen Dang Toan, Nguyen Khanh Dieu Hong, Nguyen Trung Thanh and Nguyen Thi Ha Studying on the Relation Between Conversion and Product Viscosity in Methanolysis... Briggs (2008), Biodiesel production—current state of the art and challenges Journal of Industrial Microbiology & Biotechnology, 35(5), pp 421-430 [85] Persistence Team (2008), Annual 100,000T Biodiesel Production Project College of Materials Science and Chemical Engineering Zhejiang University [86] Piyushi Nautiyal, K A Subramanian and M G Dastidar (2014), Production and characterization of biodiesel from... Kalacheva and NO Zhila (2003), Specificity of lipid composition in two Botryococcus strains, the producers of liquid hydrocarbons Russian Journal of Plant Physiology, 50(5), pp 627-633 [100] Torri C Samorì C, Samorì G, Fabbri D, Galletti P, Guerrini F, Pistocchi R and Tagliavini E (2010), Extraction of hydrocarbons from microalga Botryococcus braunii 115 with switchable solvents Bioresource Technology,... Davis M E (2008), Cooperative catalysis by silica-supported organic functional groups Chemical Society Reviews, 37(6), pp 11181126 [116] Zhonglai Li, Yichen Liu, Witold Kwapinski and James J Leahy (2014), ZrO 2modified TiO 2 nanorod composite: Hydrothermal synthesis, characterization and application in esterification of organic acid Materials Chemistry and Physics, 145(1), pp 82-89 [117] Z.W David... microalgae and extraction of total hydrocarbons: A kinetic and thermodynamic study Fuel, 119, pp 308-312 [88] Rashmi Shakeel A Khan and Z Hussain (2009), Prospects of biodiesel production from microalgae in India Renewable and Sustainable Energy Reviews, 13(9), pp 2361114 2372 [89] Raveender Vannela, Jie Sheng and Bruce E.Rittmann (2011), Evaluation of methods to extract and quantify lipids from Synchocystis... for transesterification of soybean oil and its application to biodiesel production Fuel, 87(12), 113 pp 2798-2806 [77] Minh Hien Hoang, Nguyen Cam Ha, Luu Thi Tam, Hoang Thi Lan Anh, Ngo Thi Hoai Thu and Dang Diem Hong (2014), Extraction of squalene as value-added product from the residual biomass of Schizochytrium mangrovei PQ6 during biodiesel producing process Journal of bioscience and bioengineering,... 111(3), pp 493-503 [105] Wenlei Xie and Haitao Li (2006), Alumina-supported potassium iodide as a heterogeneous catalyst for biodiesel production from soybean oil Journal of Molecular Catalysis A: Chemical, 255(1-2), pp 1-9 [106] Wenlei Xie and Xiaoming Huang (2006), Synthesis of biodiesel from soybean oil using heterogeneous KF/ZnO catalyst Catalysis Letters, 107(1-2), pp 53-59 [107] Wenlei Xie and Zhenqiang