A Water Temperature Simulation Model for Rice Paddies With Variable Water Depths

Maruyama, Atsushi; Nemoto, Minoru; Hamasaki, Toshimitsu; Ishida, Sachinobu; Kuwagata, Tsuneo

doi:10.1002/2017wr021019

Cited by 21 publications

(17 citation statements)

References 86 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Thus, the mechanisms identified in this study were not evolutionarily acquired in Buergeria lineages. Many anuran species lay eggs in temporally formed shallow water pools, such as paddy fields, whereby water temperatures can reach 36 • C (Maruyama et al, 2017). Therefore, although the present study employed rapid and acute heat stress and did not take into account acclimation effects that may occur in the field, a wide range of anuran species may have a similar transcriptomic response to heat stress as that observed in B. otai tadpoles.…”

Section: Suppressive Transcriptional Response Against Heat Stressmentioning

confidence: 98%

Transcriptomic Changes in Hot Spring Frog Tadpoles (Buergeria otai) in Response to Heat Stress

et al. 2021

View full text Add to dashboard Cite

Buergeria frog tadpoles exhibit high thermal tolerance and are occasionally found in water pools that temporarily exceed 40°C. With the aim of understanding how they can cope with the severe heat stress, we performed RNA-seq of three heat-treated (38°C) and three control (25°C) tadpoles and compared their transcriptomic profiles. We identified 382 differentially expressed transcripts. A protein-protein interaction (PPI) network analysis of these transcripts further identified hub proteins involved in protein degradation, stress granule assembly, and global suppression of DNA transcription and mRNA translation. Along with the avoidance behavior against high water temperature, these endurance mechanisms potentially support tadpoles to survive in high temperatures for short periods of time. Similar mechanisms may exist in many other amphibian species whose habitats are prone to high temperatures.

show abstract

Section: Suppressive Transcriptional Response Against Heat Stressmentioning

confidence: 98%

Transcriptomic Changes in Hot Spring Frog Tadpoles (Buergeria otai) in Response to Heat Stress

et al. 2021

View full text Add to dashboard Cite

show abstract

“…The rice-crop energy-balance model is based on the model of Ikawa et al (2018), which comprises an energy-balance submodel (Watanabe 1994;Maruyama and Kuwagata 2010;Maruyama et al 2017) and a canopy-photosynthesis submodel (de Pury and Farquhar 1997). The energy fluxes are calculated based on a so-called double-source model.…”

Section: Rice-crop Energy-balance Modelmentioning

confidence: 99%

Heat-Mitigation Effects of Irrigated Rice-Paddy Fields Under Changing Atmospheric Carbon Dioxide Based on a Coupled Atmosphere and Crop Energy-Balance Model

Ikawa

Kuwagata

Haginoya

et al. 2021

Boundary-Layer Meteorol

Self Cite

View full text Add to dashboard Cite

Known as the heat-mitigation effect, irrigated rice-paddy fields distribute a large fraction of their received energy to the latent heat during the growing season. The present hypothesis is that increased atmospheric CO2 concentration decreases the stomatal conductance of rice plants and increases the air temperature by means of an increased sensible heat flux. To test this hypothesis, a coupled regional atmospheric and crop energy-balance model is developed and applied to a 300 × 300 km2 region in Japan. Downscaling meteorological variables from grid-mean values of mixed land use (3 × 3 km2) generates realistic typical diurnal cycles of air temperature in rice paddies and adjacent residential areas. The model simulation shows that, on a typical sunny day in summer, doubling the CO2 concentration increases the daily maximum grid-mean air temperature, particularly where rice paddies are present, by up to 0.7 °C. This CO2 effect on the grid-mean air temperature is approximately half the effect of the reduction in rice-paddy area that is postulated to occur on a time scale similar to that of the atmospheric CO2 change. However, within the internal atmospheric boundary layer of the rice paddies, the CO2 effect on the air temperature (+ 0.44 °C) still exceeds the effects of the land-use change (+ 0.11 °C). These results show a potentially important interplay of plant physiological responses regarding atmospheric CO2 in the heat-mitigation effect of rice-paddy fields under a changing climate.

show abstract

“…It is necessary to accurately understand and predict the temperature environment in the paddy field and develop water‐management measures to maximize land productivity under limited natural and human resources. For water temperature modeling in paddy fields, some researchers proposed physical process models to simulate the daily dynamics of water temperature while considering the effects of vegetation layers (Maruyama & Kuwagata, 2010; Maruyama et al., 2017; Smesrud et al., 2014; Watanabe et al., 2004; Yoshida et al., 2013). Physical process models are based on specific physical theories or the integration thereof to elucidate causal relationships between interventions and outcomes.…”

Section: Introductionmentioning

confidence: 99%

Interpretable Framework of Physics‐Guided Neural Network With Attention Mechanism: Simulating Paddy Field Water Temperature Variations

Xie

Kimura

Takaki

et al. 2022

Water Resources Research

View full text Add to dashboard Cite

With the development of large‐scale rice cultivation management initiatives in East Asia, there is concern that a reduction in the number of human cultivators per unit area may lead to poor water management, which could result in decreased land productivity, owing to abnormally high‐ and low‐temperature damage to crops. Accurate simulation of paddy field water temperature is important for studying its impact on crops and providing timely information to aid in decision‐making for more efficient management under limited resources. We propose a neural‐network framework that considers the heat transfer by the vegetation canopy and applies physical‐theory constraints in its training. A novel tuning method is proposed to cope with the trade‐off between water temperature accuracy and physical consistency during training to ensure that the calculated water temperature variations in a paddy field enjoy high accuracy and physical consistency. In the experiments, the proposed framework outperforms physical process models and pure neural network models while maintaining high accuracy in the case of sparse data sets. Furthermore, an attention‐mechanism input layer is integrated into the model to rank feature importance, providing global interpretation to the proposed framework. We also perform sensitivity analysis on the physical process and propose models to compare their different strategies of feature ranking. The results show that the two methods have different sensitivities to different feature patterns, but they complement each other. In summary, the proposed model is credible and stable for practical applications and has the potential to guide more efficient paddy management.

show abstract

A Water Temperature Simulation Model for Rice Paddies With Variable Water Depths

Cited by 21 publications

References 86 publications

Transcriptomic Changes in Hot Spring Frog Tadpoles (Buergeria otai) in Response to Heat Stress

Transcriptomic Changes in Hot Spring Frog Tadpoles (Buergeria otai) in Response to Heat Stress

Heat-Mitigation Effects of Irrigated Rice-Paddy Fields Under Changing Atmospheric Carbon Dioxide Based on a Coupled Atmosphere and Crop Energy-Balance Model

Interpretable Framework of Physics‐Guided Neural Network With Attention Mechanism: Simulating Paddy Field Water Temperature Variations

Contact Info

Product

Resources

About