| [1] | Yu F, Dong W, Hu R, Long Y, Zong Y, et al. 2021. Effects of different roasting speeds on the volatile components of Xinglong coffee beans. Chinese Journal of Tropical Agriculture 42:11 |
| [2] | Mahmud MMC, Shellie RA, Keast R. 2020. Unravelling the relationship between aroma compounds and consumer acceptance: coffee as an example. Comprehensive Reviews in Food Science and Food Safety 19:2380−420 doi: 10.1111/1541-4337.12595 |
| [3] | Davis AP, Govaerts R, Bridson DM, Stoffelen P. 2006. An annotated taxonomic conspectus of the genus Coffea (Rubiaceae). Botanical Journal of the Linnean Society 152:465−512 doi: 10.1111/j.1095-8339.2006.00584.x |
| [4] | Toledo PRAB, Pezza L, Pezza HR, Toci AT. 2016. Relationship between the different aspects related to coffee quality and their volatile compounds. Comprehensive Reviews in Food Science and Food Safety 15:705−19 doi: 10.1111/1541-4337.12205 |
| [5] | Zhi M, Xu W, Wu L, Pan H, Huang W, et al. 2021. Detection and evaluation of flavor substances of roasted coffee beans in different regions. Quality and Safety of Agro-Products 3:84−90 |
| [6] | de Melo Pereira GV, de Carvalho Neto DP, Magalhães AI Jr, Vásquez ZS, Medeiros ABP, et al. 2019. Exploring the impacts of postharvest processing on the aroma formation of coffee beans – A review. Food Chemistry 272:441−52 doi: 10.1016/j.foodchem.2018.08.061 |
| [7] | de Luca S, de Filippis M, Bucci R, Magrì AD, Magrì AL, et al. 2016. Characterization of the effects of different roasting conditions on coffee samples of different geographical origins by HPLC-DAD, NIR and chemometrics. Microchemical Journal 129:348−61 doi: 10.1016/j.microc.2016.07.021 |
| [8] | Kučera L, Papoušek R, Kurka O, Barták P, Bednář P. 2016. Study of composition of Espresso coffee prepared from various roast degrees of Coffea arabica L. coffee beans. Food Chemistry 199:727−35 doi: 10.1016/j.foodchem.2015.12.080 |
| [9] | Cui D, Liu Y, Chen Y, Feng X, Lu Y, et al. 2020. Application of SPME-GC-TOFMS, E-nose, and sensory evaluation to investigate the flavor characteristics of Chinese Yunnan coffee at three different conditions (beans, ground powder, and brewed coffee). Flavour and Fragrance Journal 35:541−60 doi: 10.1002/ffj.3597 |
| [10] | Li N, Zhang F, Li M, Lin J. 2019. Effect of different roasting degree on the aroma components of robusta coffee beans. Beverage Industry 22(01):49−55 |
| [11] | Nakilcioğlu-Taş E, Ötleş S. 2019. Physical characterization of arabica ground coffee with different roasting degrees. Annals of the Brazilian Academy of Sciences 91:e20180191 doi: 10.1590/0001-3765201920180191 |
| [12] | Hu H, Song H, Wang J, Lin T, Liu X, et al. 2018. Determination of 6 kinds of chlorogenic acid by high performance liquid chromatography. Journal of Food Safety & Quality 9:1634−43 |
| [13] | Duan L, Qiu B, Dai L, Zhang S, Mei L, Kang W. 2018. Seven organic acids contents in catimor coffee detected by HPLC. Chinese Journal of Tropical Agriculture 38:100−4 |
| [14] | Pazmiño-Arteaga JD, Chagolla A, Gallardo-Cabrera C, Ruiz-Márquez AF, González-Rodríguez AT, et al. 2019. Screening for green coffee with sensorial defects due to aging during storage by MALDI-ToF mass fingerprinting. Food Analytical Methods 12:1571−76 doi: 10.1007/s12161-019-01485-9 |
| [15] | Wang Y. 2018. The Analysis of Components of Xinglong Coffee with Different Degree of Roasting and the Effect of Roasting Process on Quality, Dissertation. East University of Heilongjiang, China. pp. 20–22 |
| [16] | Zanin RC, Viegas MC, Smrke S, Yeretzian C, Kurozawa LE, et al. 2021. The role of ultrasound-assisted emulsification of roasted coffee oil on aroma profile in spray-dried microparticles and its dynamic release by PTR-ToF–MS. European Food Research and Technology 247:865−78 doi: 10.1007/s00217-020-03670-1 |