Effect of temperature and moisture on the mineralization and humification of leaf litter in a model incubation experiment

Ларионова, А. А.; Maltseva, A. N.; Gerenyu, V. O. Lopes de; Kvitkina, A. K.; Быховец, С. С.; Zolotareva, B. N.; Kudeyarov, V. N.

doi:10.1134/s1064229317020089

Cited by 31 publications

(19 citation statements)

References 11 publications

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“…It is widely accepted that the temperature response of Rs is influenced by SOM quality (Gershenson et al, 2009). Various studies have paradoxically concluded that the responses of the recalcitrant SOM components to warming could be greater than (Conant et al, 2008;Haddix et al, 2011;Knorr et al, 2005;Lefevre et al, 2014), equivalent to (Conen et al, 2006;Fang et al, 2005), or even less than (Bradford et al, 2008;Giardina & Ryan, 2000;Kurganova et al, 2012;Larionova et al, 2017;Liski et al, 1999) that of the labile organic matter. The picture is further complicated by uncertainty about the relationship between soil microbiota and SOM quality, and thus, the importance of microorganisms in regulating the temperature dependence of Rs.…”

Section: Introductionmentioning

confidence: 99%

Temperature sensitivity of SOM decomposition is linked with a K‐selected microbial community

Yang

Semënov

et al. 2021

Global Change Biology

208

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Temperature sensitivity (Q 10 ) of soil organic matter (SOM) decomposition is a crucial parameter to predict the fate of soil carbon (C) under global warming. Nonetheless, the response pattern of Q 10 to continuous warming and the underlying mechanisms are still under debate, especially considering the complex interactions between Q 10 , SOM quality, and soil microorganisms. We examined the Q 10 of SOM decomposition across a mean annual temperature (MAT) gradient from −1.9 to 5.1°C in temperate

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Section: Introductionmentioning

confidence: 99%

Temperature sensitivity of SOM decomposition is linked with a K‐selected microbial community

Yang

Semënov

et al. 2021

Global Change Biology

208

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“…On the other hand, decomposition and humification by microorganisms would cause CO 2 and CH 4 emission leading to the loss of C. Larionova al. (2017) 28 reported that the C loss caused by the CO 2 emission during the leaf decomposition and humification could attain to 20–80% of the total organic carbon depending on soil moistures. The whole procedure of the artificial decomposition was carried out in closed reactors (Fig.…”

Section: Discussionmentioning

confidence: 99%

Effects of organic fertilizers via quick artificial decomposition on crop growth

et al. 2021

Sci Rep

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Applying organic matters into the soil would help to improve soil quality and sustain crop production. In addition, the small molecular organic matters could be active in influencing soil nutrient cycling and crop development. Thus, this study has firstly induced a new technology of quick artificial decomposition to produce fertilizers containing small molecular organic compounds from crop residues and other biological wastes. The fertilizers were produced via the quick artificial decomposition from biological wastes. The small organic species in the fertilizers were identified by the LC–MS. Field experiments of kiwifruit were conducted to test the effects of fertilizers. In total, 341 species of small organic matters have been determined in the produced fertilizers. The results showed that the organic fertilizers could significantly increase the yields of kiwifruit by 15.2% in contrast with mineral fertilizer treatments. Whereas, the organic fertilizers could enhance the contents of nutritive components in kiwifruits. These results proved that the organic fertilizers containing more small organic matter could be more efficient in promoting crop production.

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“…Величина Q 10 для скорости разложения органического вещества почвы и некоторых растительных субстратов, как правило, уменьшается с ростом температуры и возрастает при разложении устойчивых органических соединений (Fierer et al, 2005;Larionova et al, 2017). В нашем эксперименте уменьшение величины Q 10 с ростом температуры прослеживалось только для E. vaginatum.…”

Section: материалы и методы исследованияunclassified

“…Для C. calyculata и смешанного образца коэффициент Q 10 , рассчитанный в интервале 12-22°C, напротив, был выше, чем в низкотемпературном диапазоне 2-12°C, что, по-видимому, можно объяснить различиями в составе исследуемых органических субстратов. Температурная чувствительность органических материалов в процессе длительной инкубации, как правило, не является одинаковой и уменьшается, демонстрируя самые высокие значения величины Q 10 в первый месяц эксперимента (Kurganova et al, 2018;Larionova et al, 2017). По-видимому, на поздних стадиях разложения, в связи с возникновением адаптации сообщества микроорганизмовдеструкторов к гидротермическим условиям в ходе длительной инкубации, температурная чувствительность скорости разложения ослабевает.…”

Section: материалы и методы исследованияunclassified

Estimate of temperature effect on the decomposition rate of peat-forming plants in a long-term laboratory experiment

Гарифулловна¹,

Николаевна²,

Овидиович³

et al. 2018

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Цель исследования. Количественная оценка влияния температуры на скорость разложения современных растений-торфообразователей олиготрофных болот южно-таежной подзоны Западной Сибири в условиях длительного модельного эксперимента.

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Effect of temperature and moisture on the mineralization and humification of leaf litter in a model incubation experiment

Cited by 31 publications

References 11 publications

Temperature sensitivity of SOM decomposition is linked with a K‐selected microbial community

Temperature sensitivity of SOM decomposition is linked with a K‐selected microbial community

Effects of organic fertilizers via quick artificial decomposition on crop growth

Estimate of temperature effect on the decomposition rate of peat-forming plants in a long-term laboratory experiment

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