| [1] |
Wang Y, Xiang Z, He H, Ren C, Sun C. 2013. Research progress of fruit wine production technology. |
| [2] |
Zhan JC, Ma TT, Huang WD, Sun XY. 2016. Research progress of artificial ageing technologies of wine. |
| [3] |
Yu JQ, Xu XX, Guo ZN, Teng F, Shuang Q, et al. 2020. Effect of ultra high pressure on seabuckthorn wine aging. |
| [4] |
Liang Z, Zhang P, Zeng XA, Fang Z. 2021. The art of flavored wine: tradition and future. |
| [5] |
Casassa LF, Ceja GM, Vega-Osorno A, du Fresne F, Llodrá D. 2021. Detailed chemical composition of Cabernet Sauvignon wines aged in French oak barrels coopered with three different stave bending techniques. |
| [6] |
Shi WQ, Zhang RT, Liu GD, Liu J, Lyu HG. 2022. Research progress on clarification, purification and aging of jujube wine and other wines. |
| [7] |
Nardin T, Roman T, Dekker S, Nicolini G, Thei F, et al. 2021. Evaluation of antioxidant supplementation in must on the development and potential reduction of different compounds involved in atypical ageing of wine using HPLC-HRMS. |
| [8] |
Cheng S, Wu T, Gao J, Han X, Huang W, et al. 2023. Color myth: anthocyanins reactions and enological approaches achieving their stabilization in the aging process of red wine. |
| [9] |
Wang M, Zhan JC, Huang WD, Kong WF, Xia GL, et al. 2021. Oak products and their influence in the winemaking process. |
| [10] |
Zhang LH, Wang XX, Zhang P, Jia XW, Chen Q, et al. 2017. Effects of artificial aging with oak on the aroma components in pomegranate brandy. |
| [11] |
Feng Z, Martínez-Lapuente L, Ayestarán B, Guadalupe Z. 2023. Volatile and sensory characterization of Tempranillo wines aged in Quercus alba oak barrels of different geographical origins in USA. |
| [12] |
Lu H, Cheng B, Lan Y, Duan C, He F. 2024. Modifications in aroma characteristics of 'Merlot' dry red wines aged in American, French and Slovakian oak barrels with different toasting degrees. |
| [13] |
García-Moreno MV, Sánchez-Guillén MM, Delgado-González MJ, Durán-Guerrero E, Rodríguez-Dodero MC, et al. 2021. Chemical content and sensory changes of Oloroso Sherry wine when aged with four different wood types. |
| [14] |
Cadahía E, Fernández de Simón B, Sanz M, Poveda P, Colio J. 2009. Chemical and chromatic characteristics of Tempranillo, Cabernet Sauvignon and Merlot wines from DO Navarra aged in Spanish and French oak barrels. |
| [15] |
Castro MC, Bortoletto AM, Silvello GC, Alcarde AR. 2020. Lignin-derived phenolic compounds in cachaça aged in new barrels made from two oak species. |
| [16] |
Ye DQ, Zheng XT, Xu XQ, Wang YH, Duan CQ, et al. 2016. Evolutions of volatile sulfur compounds of Cabernet Sauvignon wines during aging in different oak barrels. |
| [17] |
Bai M. 2016. The development of the international wine market from a global perspective and its impact on China. |
| [18] |
Martínez-Gil AM, del Alamo-Sanza M, Nevares I, Sánchez-Gómez R, Gallego L. 2020. Effect of size, seasoning and toasting level of Quercus pyrenaica Willd. wood on wine phenolic composition during maturation process with micro-oxygenation. |
| [19] |
Tao Y, García JF, Sun DW. 2014. Advances in wine aging technologies for enhancing wine quality and accelerating wine aging process. |
| [20] |
Sánchez-Palomo E, Alonso-Villegas R, Delgado JA, González-Viñas MA. 2017. Improvement of Verdejo white wines by contact with oak chips at different winemaking stages. |
| [21] |
Oberholster A, Elmendorf BL, Lerno LA, King ES, Heymann H, et al. 2015. Barrel maturation, oak alternatives and micro-oxygenation: Influence on red wine aging and quality. |
| [22] |
Gómez García-Carpintero E, Gómez Gallego MA, Sánchez-Palomo E, González Viñas MA. 2012. Impact of alternative technique to ageing using oak chips in alcoholic or in malolactic fermentation on volatile and sensory composition of red wines. |
| [23] |
Frangipane MT, De Santis D, Ceccarelli A. 2007. Influence of oak woods of different geographical origins on quality of wines aged in barriques and using oak chips. |
| [24] |
Xie C, Zhu J, Li Y. 2016. Study of liquor aging technology and aging mechanism. |
| [25] |
Shi B. 2021. The effect of ultrasonic and ultra-high pressure treatment on the sea buckthorn wine quality. Master's Thesis (in Chinese). North University of China, China |
| [26] |
Laboissière LHES, Deliza R, Barros-Marcellini AM, Rosenthal A, Camargo LMAQ, et al. 2007. Effects of high hydrostatic pressure (HHP) on sensory characteristics of yellow passion fruit juice. |
| [27] |
van Wyk S, Farid MM, Silva FVM. 2018. SO2, high pressure processing and pulsed electric field treatments of red wine: Effect on sensory, Brettanomyces inactivation and other quality parameters during one year storage. |
| [28] |
Wen HX, Bai YL, Guo XM. 2015. Effect of ultrahigh pressure on sterilization and quality of banana fruit wine. |
| [29] |
Leng H. 2014. Effects of aging technology on the quality of Cabernet Sauvignon wine. Master's Thesis (in Chinese). Qilu University of Technology, China |
| [30] |
Xia YN, Shuang Q, Yang XJ. 2021. Effect of ultra-high pressure treatment on antioxidant and flavor components of jujube wine. |
| [31] |
Van Wyk S, Silva FVM. 2017. High pressure processing inactivation of Brettanomyces bruxellensis in seven different table wines. |
| [32] |
Sun X, Li L, Ma T, Zhao F, Yu D, et al. 2016. High hydrostatic pressure treatment: an artificial accelerating aging method which did not change the region and variety non-colored phenolic characteristic of red wine. |
| [33] |
Liu Y, He F, Shi Y, Zhang B, Duan CQ. 2018. Effect of the high pressure treatments on the physicochemical properties of the young red wines supplemented with pyruvic acid. |
| [34] |
Sheng W, Yang P, Ma T, Wang B, Niu Y, et al. 2024. Process optimization of ultra-high pressure treatment of grapes: effects on the phenolic composition of red wine grapes from the Hexi Corridor region (China). |
| [35] |
Dobšinský J, Jedlička J. 2017. Biological effect of magnetic field on the fermentation of wine. |
| [36] |
Li H, Ming X, Liu Z, Xu L, Xu D, et al. 2021. Accelerating vinegar aging by combination of ultrasonic and magnetic field assistance. |
| [37] |
Zhang X, Jin X. 1989. L. B. D-B Type magnetization-induced accelerated aging and purification equipment for Baijiu. Cereals and Oils Processing 1989:27−28 (in Chinese) |
| [38] |
Dalvi-Isfahan M, Hamdami N, Xanthakis E, Le-Bail A. 2017. Review on the control of ice nucleation by ultrasound waves, electric and magnetic fields. |
| [39] |
Cai R, Yang H, He J, Zhu W. 2009. The effects of magnetic fields on water molecular hydrogen bonds. |
| [40] |
Su H, Huang W, Zhan J, Wang X. 2009. Study on the effect of magnetic field on raw anthocyanidins in fresh dry red wine. Science and Technology of Food Industry 30(11):112−15 (in Chinese) |
| [41] |
Guo D, Li J, Yue G, Li M, Hu W, et al. 2023. Effects of magnetization with neodymium magnets treatment on blueberry wine ageing. |
| [42] |
Li X, Zhang L, Peng Z, Zhao Y, Wu K, et al. 2020. The impact of ultrasonic treatment on blueberry wine anthocyanin color and its in-vitro anti-oxidant capacity. |
| [43] |
Zheng X, Zhang M, Fang Z, Liu Y. 2014. Effects of low frequency ultrasonic treatment on the maturation of steeped greengage wine. |
| [44] |
Muñoz-García R, Díaz-Maroto MC, Arévalo Villena M, Pérez-Coello MS, Alañón ME. 2023. Ultrasound and microwave techniques as physical methods to accelerate oak wood aged aroma in red wines. |
| [45] |
Ma XQ, Wang YL, Pan YB, Chen ZT, Bai WB, et al. 2023. The effect of ultrasonic aging on the color quality of wine. |
| [46] |
Leng HJ, Nie C, Men Y, Liu S, Tian W. 2014. Influence of ultrasonic wave on quality of Cabernet Sauvignon wine. The Food Industry 35(11):20−24 (in Chinese) |
| [47] |
Sánchez-Córdoba C, Durán-Guerrero E, Castro R. 2021. Olfactometric and sensory evaluation of red wines subjected to ultrasound or microwaves during their maceration or ageing stages. |
| [48] |
Shen Y, Zhang Q a, Yi X, Zhang X, Yan Y. 2015. Effect of ultrasound on total phenolic, flavonoid content and free radical scavenging activity of red wine. |
| [49] |
Sun H. 2011. Study on the aging effects of Rosa Roxburghii Tratt dry red wine by ultrasonic wave. |
| [50] |
Zhang B, Yang XS, Li NN, Zhu X, Sheng WJ, et al. 2017. Colorimetric study of malvidin-3-O-glucoside copigmented by phenolic compounds: the effect of molar ratio, temperature, pH, and ethanol content on color expression of red wine model solutions. |
| [51] |
Shi W. 2023. Study on clarification and aging technology of Blackened Jujube wine. Master's Thesis (in Chinese). Shandong Agricultural University, China |
| [52] |
Shu J, Liu D, Xie G, Zou H. 2011. Research progress on ultrasonic aging technology of alcoholic products. |
| [53] |
Qiu Q. 2016. Research on the fermentation technology, aging method and volatile components of kiwi fruit brandy. Master's Thesis (in Chinese). Sichuan Agricultural University, China |
| [54] |
Liu S. 2023. The study of the color and flavor in blueberry wine promoted by high power pulsed microwave. Master's Thesis (in Chinese). Shanghai Ocean University, China |
| [55] |
Yu L, Liu J, Feng W, Bai W. 2013. Effects of aging method on physicochemical properties and volatile aroma of mangosteen wine. |
| [56] |
Chang AC. 2003. The effects of gamma irradiation on rice wine maturation. |
| [57] |
Chang AC. 2004. The effects of different accelerating techniques on maize wine maturation. |
| [58] |
Zeng J. 2019. Study on quality changes and accelerating aging method of citrus fermented wine during aging process. Master's Thesis (in Chinese). Hunan Agriculture University, China |
| [59] |
Ma D. 2021. Study on fermentation of pear fruit wine and distillation and aging technology of brandy. Master's Thesis (in Chinese). Xinjiang Agriculture University, China |
| [60] |
Zhu SL, Gao CQ, Cui GY. 2012. Analysis of trace compositions of meilanchun sesame-flavor liquor. |
| [61] |
González-del Pozo A, Arozarena Í, Noriega MJ, Navarro M, Casp A. 2010. Short- and long-term effects of micro-oxygenation treatments on the colour and phenolic composition of a Cabernet Sauvignon wine aged in barrels and/or bottles. |
| [62] |
Kang W, Li H, Yang X, Duan X. 2006. Effect of micro-oxygenation on wine. Food and Fermentation Industries 2006(5):77−81 |
| [63] |
Zhang JX, Li YS, Hao XY. 2011. Application on micro-oxygenation in wine making-process. |
| [64] |
Gambuti A, Rinaldi A, Ugliano M, Moio L. 2013. Evolution of phenolic compounds and astringency during aging of red wine: effect of oxygen exposure before and after bottling. |
| [65] |
Ugliano M, Dieval JB, Siebert TE, Kwiatkowski M, Aagaard O, et al. 2012. Oxygen consumption and development of volatile sulfur compounds during bottle aging of two shiraz wines. influence of pre- and postbottling controlled oxygen exposure. |
| [66] |
Cejudo-Bastante MJ, Hermosín-Gutiérrez I, Pérez-Coello MS. 2011. Micro-oxygenation and oak chip treatments of red wines: effects on colour-related phenolics, volatile composition and sensory characteristics. Part I: Petit Verdot wines. |
| [67] |
Zheng S, Li Y, Wu L, Liu Y, Zhang Z, et al. 2007. Production of crude ethanol (crude alcohol) from sweet sorghum stems - the key techniques for solid fermentation. Liquor Making 34(4):47−48 |
| [68] |
Zhou X, Gao C, Wang X. 2010. Aging wines with oak chips and ultrasound. China Brewing 2010(8):83−87 |
| [69] |
Wang L. 2008. Study on technology of wine aging in stainless steel tank with innerstaves. Master's Thesis (in Chinese). Northwest A&F University, China |
| [70] |
Del Carmen Llaudy M, Canals R, González-Manzano S, Canals JM, Santos-Buelga C, et al. 2006. Influence of micro-oxygenation treatment before oak aging on phenolic compounds composition, astringency, and color of red wine. |
| [71] |
Cai PF, Shao CZ, Zhang N, Zhang FG, Xin CH. 2014. The conjecture for characteristic flavor compounds of sesame flavor liquor. Liquor-Making 41(5):76−78 (in Chinese) |
| [72] |
Yuan J, Yin JY, Gao HY. 2008. Advances in application of fingerprint technology in Chinese spirit industry. |
| [73] |
Ruiz-Muñoz M, Cordero-Bueso G, Benítez-Trujillo F, Martínez S, Pérez F, et al. 2020. Rethinking about flor yeast diversity and its dynamic in the "criaderas and soleras" biological aging system. |
| [74] |
Muñoz D, Peinado RA, Medina M, Moreno J. 2008. Effect of Saccharomyces cerevisiae F12 on volatile compounds in wines at three different stages of industrial biological ageing. |
| [75] |
Serra-Cayuela A, Aguilera-Curiel MA, Riu-Aumatell M, Buxaderas S, López-Tamames E. 2013. Browning during biological aging and commercial storage of Cava sparkling wine and the use of 5-HMF as a quality marker. |