The Experts below are selected from a list of 294 Experts worldwide ranked by ideXlab platform
Alireza Iranbakhsh - One of the best experts on this subject based on the ideXlab platform.
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Transcriptional responses following seed priming with cold plasma and Electromagnetic Field in Salvia nemorosa L.
Journal of Theoretical and Applied Physics, 2020Co-Authors: Maryam Ghaemi, Ahmad Majd, Alireza IranbakhshAbstract:This study was conducted to monitor the plant responses to seed priming with Electromagnetic Fields (0, 4, or 6 mT) or cold plasma (0, 80, or 100 s) in Salvia nemorosa . The cold plasma or Electromagnetic Field treatments significantly increased shoot fresh weight (49%), root fresh weight (41%), and root length (56%). The results highlighted that seed priming with cold plasma or the Electromagnetic Field is an effective method to modify seedling growth. The Electromagnetic Field and plasma treatments upregulated the AREB1 gene (mean = 3.9-fold). Except for the Electromagnetic Field of 4mT, the other treatments stimulated expressions of the WRKY1 gene by an average of 6.7-fold relative to the control. The cold plasma or Electromagnetic Field also induced the expression of cinnamoyl-CoA reductases (CCR2) gene (mean = fourfold). These treatments also changed the expression of the rosmarinic acid synthase by an average of sixfold. These findings may improve our knowledge of plant reactions to cold plasma and Electromagnetic Field for possible functions in seed technology.
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Transcriptional responses following seed priming with cold plasma and Electromagnetic Field in Salvia nemorosa L.
Journal of Theoretical and Applied Physics, 2020Co-Authors: Maryam Ghaemi, Ahmad Majd, Alireza IranbakhshAbstract:This study was conducted to monitor the plant responses to seed priming with Electromagnetic Fields (0, 4, or 6 mT) or cold plasma (0, 80, or 100 s) in Salvia nemorosa . The cold plasma or Electromagnetic Field treatments significantly increased shoot fresh weight (49%), root fresh weight (41%), and root length (56%). The results highlighted that seed priming with cold plasma or the Electromagnetic Field is an effective method to modify seedling growth. The Electromagnetic Field and plasma treatments upregulated the AREB1 gene (mean = 3.9-fold). Except for the Electromagnetic Field of 4mT, the other treatments stimulated expressions of the WRKY1 gene by an average of 6.7-fold relative to the control. The cold plasma or Electromagnetic Field also induced the expression of cinnamoyl-CoA reductases (CCR2) gene (mean = fourfold). These treatments also changed the expression of the rosmarinic acid synthase by an average of sixfold. These findings may improve our knowledge of plant reactions to cold plasma and Electromagnetic Field for possible functions in seed technology.
Maryam Ghaemi - One of the best experts on this subject based on the ideXlab platform.
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Transcriptional responses following seed priming with cold plasma and Electromagnetic Field in Salvia nemorosa L.
Journal of Theoretical and Applied Physics, 2020Co-Authors: Maryam Ghaemi, Ahmad Majd, Alireza IranbakhshAbstract:This study was conducted to monitor the plant responses to seed priming with Electromagnetic Fields (0, 4, or 6 mT) or cold plasma (0, 80, or 100 s) in Salvia nemorosa . The cold plasma or Electromagnetic Field treatments significantly increased shoot fresh weight (49%), root fresh weight (41%), and root length (56%). The results highlighted that seed priming with cold plasma or the Electromagnetic Field is an effective method to modify seedling growth. The Electromagnetic Field and plasma treatments upregulated the AREB1 gene (mean = 3.9-fold). Except for the Electromagnetic Field of 4mT, the other treatments stimulated expressions of the WRKY1 gene by an average of 6.7-fold relative to the control. The cold plasma or Electromagnetic Field also induced the expression of cinnamoyl-CoA reductases (CCR2) gene (mean = fourfold). These treatments also changed the expression of the rosmarinic acid synthase by an average of sixfold. These findings may improve our knowledge of plant reactions to cold plasma and Electromagnetic Field for possible functions in seed technology.
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Transcriptional responses following seed priming with cold plasma and Electromagnetic Field in Salvia nemorosa L.
Journal of Theoretical and Applied Physics, 2020Co-Authors: Maryam Ghaemi, Ahmad Majd, Alireza IranbakhshAbstract:This study was conducted to monitor the plant responses to seed priming with Electromagnetic Fields (0, 4, or 6 mT) or cold plasma (0, 80, or 100 s) in Salvia nemorosa . The cold plasma or Electromagnetic Field treatments significantly increased shoot fresh weight (49%), root fresh weight (41%), and root length (56%). The results highlighted that seed priming with cold plasma or the Electromagnetic Field is an effective method to modify seedling growth. The Electromagnetic Field and plasma treatments upregulated the AREB1 gene (mean = 3.9-fold). Except for the Electromagnetic Field of 4mT, the other treatments stimulated expressions of the WRKY1 gene by an average of 6.7-fold relative to the control. The cold plasma or Electromagnetic Field also induced the expression of cinnamoyl-CoA reductases (CCR2) gene (mean = fourfold). These treatments also changed the expression of the rosmarinic acid synthase by an average of sixfold. These findings may improve our knowledge of plant reactions to cold plasma and Electromagnetic Field for possible functions in seed technology.
D. N. Makarov - One of the best experts on this subject based on the ideXlab platform.
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Quantum entanglement of a harmonic oscillator with an Electromagnetic Field
Scientific reports, 2018Co-Authors: D. N. MakarovAbstract:At present, there are many methods for obtaining quantum entanglement of particles with an Electromagnetic Field. Most methods have a low probability of quantum entanglement and not an exact theoretical apparatus based on an approximate solution of the Schrodinger equation. There is a need for new methods for obtaining quantum-entangled particles and mathematically accurate studies of such methods. In this paper, a quantum harmonic oscillator (for example, an electron in a magnetic Field) interacting with a quantized Electromagnetic Field is considered. Based on the exact solution of the Schrodinger equation for this system, it is shown that for certain parameters there can be a large quantum entanglement between the electron and the Electromagnetic Field. Quantum entanglement is analyzed on the basis of a mathematically exact expression for the Schmidt modes and the Von Neumann entropy.
Ahmad Majd - One of the best experts on this subject based on the ideXlab platform.
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Transcriptional responses following seed priming with cold plasma and Electromagnetic Field in Salvia nemorosa L.
Journal of Theoretical and Applied Physics, 2020Co-Authors: Maryam Ghaemi, Ahmad Majd, Alireza IranbakhshAbstract:This study was conducted to monitor the plant responses to seed priming with Electromagnetic Fields (0, 4, or 6 mT) or cold plasma (0, 80, or 100 s) in Salvia nemorosa . The cold plasma or Electromagnetic Field treatments significantly increased shoot fresh weight (49%), root fresh weight (41%), and root length (56%). The results highlighted that seed priming with cold plasma or the Electromagnetic Field is an effective method to modify seedling growth. The Electromagnetic Field and plasma treatments upregulated the AREB1 gene (mean = 3.9-fold). Except for the Electromagnetic Field of 4mT, the other treatments stimulated expressions of the WRKY1 gene by an average of 6.7-fold relative to the control. The cold plasma or Electromagnetic Field also induced the expression of cinnamoyl-CoA reductases (CCR2) gene (mean = fourfold). These treatments also changed the expression of the rosmarinic acid synthase by an average of sixfold. These findings may improve our knowledge of plant reactions to cold plasma and Electromagnetic Field for possible functions in seed technology.
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Transcriptional responses following seed priming with cold plasma and Electromagnetic Field in Salvia nemorosa L.
Journal of Theoretical and Applied Physics, 2020Co-Authors: Maryam Ghaemi, Ahmad Majd, Alireza IranbakhshAbstract:This study was conducted to monitor the plant responses to seed priming with Electromagnetic Fields (0, 4, or 6 mT) or cold plasma (0, 80, or 100 s) in Salvia nemorosa . The cold plasma or Electromagnetic Field treatments significantly increased shoot fresh weight (49%), root fresh weight (41%), and root length (56%). The results highlighted that seed priming with cold plasma or the Electromagnetic Field is an effective method to modify seedling growth. The Electromagnetic Field and plasma treatments upregulated the AREB1 gene (mean = 3.9-fold). Except for the Electromagnetic Field of 4mT, the other treatments stimulated expressions of the WRKY1 gene by an average of 6.7-fold relative to the control. The cold plasma or Electromagnetic Field also induced the expression of cinnamoyl-CoA reductases (CCR2) gene (mean = fourfold). These treatments also changed the expression of the rosmarinic acid synthase by an average of sixfold. These findings may improve our knowledge of plant reactions to cold plasma and Electromagnetic Field for possible functions in seed technology.
Peter Russer - One of the best experts on this subject based on the ideXlab platform.
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Quantum computing algorithm for Electromagnetic Field simulation
Quantum Information Processing, 2010Co-Authors: Siddhartha Sinha, Peter RusserAbstract:Quantum computing offers new concepts for the simulation of complex physical systems. A quantum computing algorithm for Electromagnetic Field simulation is presented here. The Electromagnetic Field simulation is performed on the basis of the Transmission Line Matrix (TLM) method. The Hilbert space formulation of TLM allows us to obtain a time evolution operator for the TLM method, which can then be interpreted as the time evolution operator of a quantum system, thus yielding a quantum computing algorithm. Further, the quantum simulation is done within the framework of the quantum circuit model of computation. Our aim has been to address the design problem in Electromagnetics—given an initial condition and a final Field distribution, find the structures which satisfy these. Quantum computing offers us the possibility to solve this problem from first principles. Using quantum parallelism we simulate a large number of Electromagnetic structures in parallel in time and then try to filter out the ones which have the required Field distribution.
