ICCK

Deke Xing

School of Agricultural Engineering, Jiangsu University, China

Section 01

Academic Profile

Deke Xing holds a Ph.D. in Geochemistry, M.S. in Agricultural Bioenvironment and Energy Engineering, and B.S. in Environmental Science. His research focuses on plant electrobiology, plant stress physiological ecology, and water-saving irrigation. He has successfully applied electrobiological techniques to research in plant stress physiological ecology and water-saving irrigation. By employing electrobiological techniques, he investigated the dynamic characteristics of intracellular water utilization in various plant species under stresses. Meanwhile, he developed models that correlates electrobiological parameters with the plant's net photosynthetic rate and growth status, allowing for the precise prediction of both the net photosynthetic rate and growth rate. These models have also been applied to the precision irrigation. He serves as Associate Editor of Journal of Plant Electrobiology.

Section 02

Editorial Roles

This user currently does not serve as an editor for any ICCK journals.

Section 03

ICCK Publications

Free Access | Research Article | 30 March 2026
Intracellular Water Dynamic Traits in Detached Leaves of Two Brassicaceae Plant Species under Saturated and Non-saturated Water Conditions
Journal of Plant Electrobiology | Volume 1, Issue 1: 42-57, 2026 | DOI: 10.62762/JPE.2025.989558
Abstract
Investigating the intracellular water dynamics within leaves will clarify plant responses to different water conditions and provide a theoretical basis for enhancing water-use efficiency. Detached leaves of Chinese flowering cabbage (Brassica campestris L. ssp. chinensis var. utilis Tsen et Lee) and broccoli (Brassica oleracea L. var. italica Plenck) were used as experimental materials in this study. Electrophysiological parameters of the leaves under saturated and non-saturated conditions were measured, and the intracellular water, nutrient, and energy related indices were calculated according to Nernst equation. The acceleration (a) reflecting the change rate of water transport rate in cel... More >

Graphical Abstract
Intracellular Water Dynamic Traits in Detached Leaves of Two Brassicaceae Plant Species under Saturated and Non-saturated Water Conditions
Free Access | Research Article | 12 February 2026
Salt Adaptation in Aegiceras Corniculatum: Electrophysiology, Gene Expression, and Energy Trade-Offs
Journal of Plant Electrobiology | Volume 1, Issue 1: 7-31, 2026 | DOI: 10.62762/JPE.2025.184208
Abstract
The integration of physical and chemical processes underpins life. Plant cells function as bioelectrical units, storing and converting energy through capacitive, inductive, and resistive properties. This study elucidates the electrophysiological and molecular mechanisms governing salt transport and energy allocation in Aegiceras corniculatum leaves under combined salinity-waterlogging stress (T1: 0.1 M NaCl + 2 h; T2: 0.2 M NaCl + 4 h; T3: 0.4 M NaCl + 6 h). Results demonstrate that leaf intracellular water-salt transport dynamics, coupled with salt-transport gene expression, coordinately regulate active/passive transport, vacuolar compartmentalization, cytoplasmic Na+ levels, and excretion.... More >

Graphical Abstract
Salt Adaptation in Aegiceras Corniculatum: Electrophysiology, Gene Expression, and Energy Trade-Offs
Open Access | Editorial | 21 September 2025 | Cited: Scopus 1
Inaugural Editorial for the Journal of Plant Electrobiology
Journal of Plant Electrobiology | Volume 1, Issue 1: 1-6, 2025 | DOI: 10.62762/JPE.2025.322792
Abstract
This editorial defines the core mission, academic orientation, and six interrelated thematic pillars of Journal of Plant Electrobiology (JPE), which is a peer-reviewed international journal dedicated to advancing the interdisciplinary fusion of electronics, bioenergetics, biophysics, and plant science. JPE aims to showcase innovative researches that leverage electronic principles and technologies to address fundamental and applied questions in plant biology, foster cross-disciplinary collaboration, and accelerate the translation of plant electrobiology breakthroughs into solutions for sustainable agriculture, plant stress resilience, and environmental stewardship. Against the backdrop of rap... More >