Trumpet Number One

Stomatal Processes in Daytime and Night time Plants and Trees

 

Page published 13th March 2025

Trumpet Number One Chemistry in a nutshell

Imagine the time and money spent just to deceive you on this military event known as Trumpet Number One in the Holy Bible.

When it is all done – you recognise it as chemistry – The scales of the Blue/Dark/Black Horse rider the Democrats leader has a set of scales in his hand. What God is showing is that Globalist Bankers have had the scales out and worked out the balances of nature and now deploy them in an evil way to disable. destroy and kill you in every way possible.

Flowing is the Stomatal Processes the balances in plants, crops and trees.  In short it is Trumpet Number One in a small chapter. Everything else that has been done, has been done to discover this and destroy at the appointed time.

Stomatal Processes in Daytime and Night time Plants and Trees

Introduction

Stomata are microscopic pores found on the surface of leaves and stems, primarily responsible for gas exchange and water regulation in plants. These pores open and close in response to environmental conditions, allowing the uptake of carbon dioxide (CO₂) for photosynthesis while minimizing water loss through transpiration. The behaviour of stomata varies significantly between plants adapted to daytime photosynthesis (C3 and C4 plants) and those adapted to night time carbon fixation (CAM plants). Understanding these differences is essential for comprehending plant physiology and adaptation to different ecosystems.

Stomatal Processes in Daytime Plants and Trees

Most plants, including the majority of trees and crops, perform photosynthesis during the day. Their stomatal activity is regulated by several key factors, including light intensity, humidity, temperature, and carbon dioxide concentration.

Mechanism of Stomatal Opening and Closing

1. Morning Activation: When sunlight increases in the morning, blue light stimulates photoreceptors in guard cells, triggering the activation of proton pumps. These pumps expel hydrogen ions (H⁺), leading to the uptake of potassium (K⁺) and chloride (Cl⁻) ions into the guard cells.
2. Water Influx: The accumulation of ions reduces the water potential inside guard cells, causing water to enter via osmosis. This influx swells the guard cells, making them turgid and resulting in the opening of the stomatal pore.
3. Photosynthesis and Gas Exchange: Once the stomata are open, carbon dioxide enters for photosynthesis while oxygen and water vapor exit. During peak sunlight hours, stomata remain open to maximize carbon assimilation.
4. Afternoon Regulation: As temperature rises and water availability decreases, plants regulate stomatal opening to prevent excessive water loss. Some plants may partially close their stomata in extreme heat to avoid desiccation.
5. Evening Closure: As the sun sets, light intensity drops, reducing the demand for CO₂. Potassium and chloride ions leave the guard cells, leading to water efflux and subsequent stomatal closure.

Environmental Factors Influencing Stomatal Activity

• Light: Higher light intensity promotes stomatal opening, while darkness leads to closure.
• Humidity: Low humidity increases transpiration rates, potentially causing partial stomatal closure to conserve water.
• Temperature: High temperatures can lead to excessive water loss, prompting stomata to close as a protective measure.
• CO₂ Concentration: Increased atmospheric CO₂ levels can lead to partial stomatal closure, reducing transpiration while maintaining photosynthesis efficiency.

Stomatal Processes in Night time Plants and Trees (CAM Plants)

Unlike typical daytime plants, Crassulacean Acid Metabolism (CAM) plants have evolved a unique stomatal behaviour to adapt to arid environments. These plants, including cacti, succulents, and certain epiphytes, open their stomata at night to minimize water loss while still obtaining CO₂ for photosynthesis.

Mechanism of Stomatal Activity in CAM Plants

1. Night time Opening: CAM plants open their stomata at night to take in CO₂ when temperatures are lower and humidity is higher, reducing water loss through transpiration.
2. CO₂ Storage as Malic Acid: Instead of immediately using CO₂ in the Calvin cycle, CAM plants convert it into malic acid, which is stored in vacuoles until daylight.
3. Daytime Closure and Photosynthesis: As the sun rises, stomata close to prevent water loss. The stored malic acid is then broken down to release CO₂ internally, allowing photosynthesis to occur in the absence of stomatal gas exchange.

Environmental and Adaptive Significance of CAM Plants

• Water Conservation: By keeping stomata closed during the day, CAM plants dramatically reduce transpiration, making them well-suited to desert and arid conditions.
• Efficient Carbon Use: CAM plants can survive in environments where C3 and C4 plants struggle due to excessive water loss.
• Reversible Mechanism: Some plants, known as facultative CAM plants, can switch between CAM and C3 pathways depending on water availability.

Disruption of Plant and Tree Stomatal Processes as per Trumpet Number One

According to the Holy Bible, Revelation 8:7 (King James Version):

“The first angel sounded, and there followed hail and fire mingled with blood, and they were cast upon the earth: and the third part of trees was burnt up, and all green grass was burnt up.”

This passage describes a catastrophic event affecting vegetation on a massive scale. The disruption of plants and trees is caused by environmental contamination through a combination of hail, fire (fire here as in poison not in flame), and blood.

Mechanism of Stomatal Disruption

1. Blood/Plasma Coating on Foliage: When all plants, crops, and one-third of the trees are coated in blood and plasma, the organic compounds in the plasma create a transient medium for absorbing airborne gases, particularly methane and other pollutants released by human activities like deep-sea mining.
2. Hail Vapor Interaction: The presence of hail vapor enhances condensation of gases in the atmosphere, further concentrating the contaminants on plant surfaces. The moisture from the hail also facilitates deeper penetration of these substances into the stomatal pores.
3. Overloading of Gas Exchange Processes:
   • Methane and other gases dissolve into the plasma film, leading to abnormal gas uptake.
   • The increased concentration of methane in the stomatal cavity disrupts the normal diffusion gradient, interfering with CO₂ absorption and photosynthesis.
   • Excessive gas uptake overwhelms the plant’s ability to regulate transpiration, leading to metabolic stress and eventual stomatal failure.
4. Toxic Effects and Plant Death: As the stomatal processes become severely impaired, plants experience a build up of toxic gases within their tissues. This results in:
   • Rapid dehydration due to disrupted transpiration.
   • Cellular damage from methane and other reactive gases.
   • Failure of photosynthetic mechanisms, ultimately causing large-scale plant and tree mortality.

Conclusion

The environmental disruption caused by Trumpet Number One presents a catastrophic scenario for global vegetation. The introduction of blood/plasma, combined with methane gas accumulation and hail vapor condensation, directly interferes with stomatal function. This disruption leads to an overload of toxic gases, rendering plants unable to sustain photosynthesis and causing the total destruction of all crops and green grass, which is effectively “burnt up” as per Revelation 8:7. Additionally, one-third of the trees are destroyed, highlighting the apocalyptic consequences of this event. Understanding the vulnerability of plant physiology in such extreme conditions emphasizes the devastating impact of atmospheric and environmental upheavals.

Result and Damage question

 

When this military attack is executed on the world where are you going to get the food to feed your children and grandchildren?