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16. de Souza, H.J.P.L.; Muñoz, F.; Mendonça, R.T.; Sáez, K.; Olave, R.; Segura, C.; de Souza, D.P.; Protásio, T.D.P.; Rodríguez-Soalleiro, R. Influence of lignin distribution, physicochemical characteristics and microstructure on the quality of biofuel pellets made from four different types of biomass. Renew. Energy 2021, 163, 1802–1816. [CrossRef]

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21. EN ISO 17829:2015; Biocombustibles Sólidos. Determinación de la Longitud y el Diámetro de Pellets. Asociación Española de Normalización y Certificación (AENOR): Madrid, Spain, 2016; 10p.
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22. EN ISO 17831-1:2015; Biocombustibles Sólidos. Determinación de la Durabilidad Mecánica de Pellets y Briquetas. Parte 1: Pellets. Asociación Española de Normalización y Certificación (AENOR): Madrid, Spain, 2016; 13p.
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25. EN ISO 18125:2017; Biocombustibles Sólidos. Determinación del Poder Calorífico. Asociación Española de Normalización: Madrid, Spain, 2018; 68p.
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6. Insights into Properties of Biomass Energy Pellets Made from Mixtures of Woody and Non-Woody Biomass: A Meta-Analysis. (2023). Vlosky, Richard ; Bandara, Rangika ; Rupasinghe, Rajitha Lakshan ; Perera, Priyan ; Amarasekera, Hiran.
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7. Pyrolysis and Extraction of Bark in a Biorefineries Context: A Critical Review. (2023). En, Umut ; Pereira, Helena ; Esteves, Bruno.
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8. A Multidisciplinary Approach for an Effective and Rational Energy Transition in Crete Island, Greece. (2022). Skoulou, Vasiliki ; Pappa, Stavroula ; Antonakakis, Ioannis ; Dakanali, Eirini ; Christakis, Dimitris ; al Katsaprakakis, Dimitris ; Condaxakis, Constantinos ; Michopoulos, Apostolos ; Maragkaki, Aggeliki.
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9. Avocado Tree Pruning Pellets ( Persea americana Mill.) for Energy Purposes: Characterization and Quality Evaluation. (2022). Berrueta-Soriano, Victor Manuel ; Tauro, Raul ; Alvarado-Flores, Jose Juan ; Rutiaga-Quiones, Jose Guadalupe ; Soria-Gonzalez, Jose Alberto.
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10. A Review on the Effects of Pretreatment and Process Parameters on Properties of Pellets. (2022). Zhang, Yifei ; Li, Wentao ; Wang, Mingfeng ; Meng, Fanbin.
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11. Wood pellet quality depending on dendromass species. (2022). Stachowicz, Pawe ; Dudziec, Pawe ; Stolarski, Mariusz J.
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12. Valorization of forest waste biomass by catalyzed pyrolysis. (2022). Ramos, Marta ; Ameixa, Marcelo ; Rijo, Bruna ; Soares, Ana Paula.
    In: Energy.
    RePEc:eee:energy:v:243:y:2022:i:c:s0360544221030152.

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13. Insights into the product quality and energy requirements for solid biofuel production: A comparison of hydrothermal carbonization, pyrolysis and torrefaction of olive tree pruning. (2022). Gomez, X ; Gonzalez-Castao, M ; Sanchez, M E ; Rosas, J G ; Gonzalez-Arias, J ; Cara-Jimenez, J.
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14. Eucalyptus globulus Coppices in Portugal: Influence of Site and Percentage of Residues Collected for Energy. (2021). Malico, Isabel ; Gonalves, Ana Cristina.
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15. Valorization of Prosopis juliflora Woody Biomass in Northeast Brazilian through Dry Torrefaction. (2021). Beisl, Silvio Alexandre ; de Mattos, Jose Airton ; Carvalho, Heloysa Martins ; de Oliveira, Giulyane Felix ; Torres, Ednildo Andrade ; Alves, Carine Tondo.
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16. Torrefaction of biomass: Production of enhanced solid biofuel from municipal solid waste and other types of biomass. (2021). Ashri, Wan Mohd ; Abdul, Muhamad Fazly ; Abdulyekeen, Kabir Abogunde ; Umar, Ahmad Abulfathi.
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17. An experimental assessment of Eucalyptus urosemente energy potential for biomass production in Brazil. (2019). de Almeida, Pedro Eduardo ; da Silva, Luis Henrique ; Ribeiro, Carlos Antonio.
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18. A comprehensive study of sawdust torrefaction in a dual-compartment slot-rectangular spouted bed reactor. (2019). Wang, Ziliang ; Grace, John R ; Lim, Jim C.
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19. Production of biochars from textile fibres through torrefaction and their characterisation. (2019). Yanik, Jale ; Hanolu, Alper ; Ay, Ahmet.
    In: Energy.
    RePEc:eee:energy:v:166:y:2019:i:c:p:664-673.

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20. Effect of ethanol on Mulberry bark hydrothermal liquefaction and bio-oil chemical compositions. (2018). Zhang, Yanjuan ; Jia, Shuang ; Mi, Shuai ; Li, Mingfei ; Zhu, Jingxian ; Chen, Congjin ; Huang, Zuqiang ; Tong, Zhangfa.
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21. Non-oxidative torrefaction of biomass to enhance its fuel properties. (2018). Matos, Maria ; Bueno, Julio L ; Nogueiro, Dositeo ; Pizarro, Consuelo ; Alvarez, Ana.
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22. Study of light, middle and severe torrefaction and effects of extractives and chemical compositions on torrefaction process by thermogravimetric analysis in five fast-growing plantations of Costa Rica. (2018). Moya, Roger ; Gaitan-Alvarez, Johanna ; Rodriguez-Zuiga, Ana ; Puente-Urbina, Allen.
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23. Effect of torrefaction on physiochemical characteristics and grindability of stem wood, stump and bark. (2018). Khalil, R ; Skreiberg, O ; Gronli, M ; Wang, L ; Jakab, E ; Barta-Rajnai, E ; Czegeny, Z.
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24. In situ catalytic fast pyrolysis of crude and torrefied Eucalyptus globulus using carbon aerogel-supported catalysts. (2017). Jimenez, Romel ; Olivera, Patricia ; Capiro, Oscar Gomez ; Arteaga-Perez, Luis E ; Ronsse, Frederik ; Delgado, Aaron ; Romero, Romina .
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25. Comparative study on the thermal behavior of untreated and various torrefied bark, stem wood, and stump of Norway spruce. (2017). Khalil, R ; Skreiberg, O ; Gronli, M ; Wang, L ; Jakab, E ; Barta-Rajnai, E ; Sebestyen, Z ; Czegeny, Z.
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