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Specifically Designed for Swamp Red Pseudomonads (PSB-S) and Certain Algae
Product Features
Dedicated Spectrum, Scientifically Formulated, Low Light Degradation, High Light Efficiency.
Solving Issues in Photosynthetic Bacteria Cultivation: Slow Reproduction Rates, Low Photosynthetic Bacteria Density, Low Activity, Low OD Values, etc.
Custom Light Sources for Algae Cultivation.
Comparison of Cultivation Results under Different Lighting Conditions
Practical Application Results
Why Choose GMY Photosynthetic Bacteria Culture light?
GMY Photosynthetic Bacteria Culture Light | Other Photosynthetic Bacteria Culture Lamps |
· The light formula (spectrum, light intensity) is highly optimized. · Striped fabric light design, flexible and offering higher uniformity. · Low power consumption: 100W per unit area for fabric light, 200W for dual-side fabric lighting. · Long LED lifespan. · Cold light source, high light efficiency, low heat dissipation from the light-emitting surface, enabling close proximity to the culture medium. | · Standard lighting spectrum, not specifically designed for photosynthetic bacteria cultivation. · Uneven light distribution: excessive light intensity near the light, insufficient light intensity farther from the light. · High power consumption: particularly halogen lights, with power consumption exceeding 400W per unit area. · Short halogen light lifespan: typically around 500-600 hours. Halogen lights are not suitable for continuous operation as prolonged use causes filament aging, affecting brightness and lifespan. · High heat dissipation in halogen lights, prone to heat accumulation, requiring additional temperature control costs. · Halogen light design is not suitable for multi-layer cultivation systems. |
Cultivation Effects of
GMY Photosynthetic Bacteria Culture Lights
Cultivation Effects of
Other Photosynthetic Bacteria Culture Lamps
2.GMY Photosynthetic Bacteria Culture Light vs. Natural Light Cultivation
GMY Photosynthetic Bacteria Culture Light | Natural Light Cultivation |
· Provides continuous and stable lighting. · Enables larger area coverage of the culture medium. · Temperature and humidity are controllable. · Suitable for multi-layer cultivation. · Facilitates stable and efficient production. · Results in highly concentrated and high-quality culture medium. | · Unstable lighting conditions: lighting is interrupted at night, excessive light intensity during sunny days, insufficient light intensity on cloudy days, and prolonged rainy weather causes severe damage to bacterial cultivation, potentially leading to complete crop failure. · Temperature control is difficult, with significant seasonal variations in cultivation conditions. The optimal growth temperature for photosynthetic bacteria is between 25-30°C. |
Product Design Details
PVC Ports: Secure and durable connections, supporting series connection.
High-Intensity LED Beads: High light efficiency, optimized for photosynthetic bacteria cultivation.
Aluminum light Body: Efficient heat dissipation, ensuring stable light performance.
High-Transmittance PC light Cover: Available in both matte white and transparent options, durable and aesthetically pleasing.
Product Specifications
Input Voltage (V): AC 187-264
Power (W): 24
Luminous Flux (lm): 240
Spectral Range (nm): 380-1000
Lifespan (H): 15,000
Ingress Protection Rating: IP20
Light Efficiency (lm/W): 30
Photosynthetic Photon Flux Density (μmol/㎡·s): 19±5
Specifically Designed for Swamp Red Pseudomonads (PSB-S) and Certain Algae
Product Features
Dedicated Spectrum, Scientifically Formulated, Low Light Degradation, High Light Efficiency.
Solving Issues in Photosynthetic Bacteria Cultivation: Slow Reproduction Rates, Low Photosynthetic Bacteria Density, Low Activity, Low OD Values, etc.
Custom Light Sources for Algae Cultivation.
Comparison of Cultivation Results under Different Lighting Conditions
Practical Application Results
Why Choose GMY Photosynthetic Bacteria Culture light?
GMY Photosynthetic Bacteria Culture Light | Other Photosynthetic Bacteria Culture Lamps |
· The light formula (spectrum, light intensity) is highly optimized. · Striped fabric light design, flexible and offering higher uniformity. · Low power consumption: 100W per unit area for fabric light, 200W for dual-side fabric lighting. · Long LED lifespan. · Cold light source, high light efficiency, low heat dissipation from the light-emitting surface, enabling close proximity to the culture medium. | · Standard lighting spectrum, not specifically designed for photosynthetic bacteria cultivation. · Uneven light distribution: excessive light intensity near the light, insufficient light intensity farther from the light. · High power consumption: particularly halogen lights, with power consumption exceeding 400W per unit area. · Short halogen light lifespan: typically around 500-600 hours. Halogen lights are not suitable for continuous operation as prolonged use causes filament aging, affecting brightness and lifespan. · High heat dissipation in halogen lights, prone to heat accumulation, requiring additional temperature control costs. · Halogen light design is not suitable for multi-layer cultivation systems. |
Cultivation Effects of
GMY Photosynthetic Bacteria Culture Lights
Cultivation Effects of
Other Photosynthetic Bacteria Culture Lamps
2.GMY Photosynthetic Bacteria Culture Light vs. Natural Light Cultivation
GMY Photosynthetic Bacteria Culture Light | Natural Light Cultivation |
· Provides continuous and stable lighting. · Enables larger area coverage of the culture medium. · Temperature and humidity are controllable. · Suitable for multi-layer cultivation. · Facilitates stable and efficient production. · Results in highly concentrated and high-quality culture medium. | · Unstable lighting conditions: lighting is interrupted at night, excessive light intensity during sunny days, insufficient light intensity on cloudy days, and prolonged rainy weather causes severe damage to bacterial cultivation, potentially leading to complete crop failure. · Temperature control is difficult, with significant seasonal variations in cultivation conditions. The optimal growth temperature for photosynthetic bacteria is between 25-30°C. |
Product Design Details
PVC Ports: Secure and durable connections, supporting series connection.
High-Intensity LED Beads: High light efficiency, optimized for photosynthetic bacteria cultivation.
Aluminum light Body: Efficient heat dissipation, ensuring stable light performance.
High-Transmittance PC light Cover: Available in both matte white and transparent options, durable and aesthetically pleasing.
Product Specifications
Input Voltage (V): AC 187-264
Power (W): 24
Luminous Flux (lm): 240
Spectral Range (nm): 380-1000
Lifespan (H): 15,000
Ingress Protection Rating: IP20
Light Efficiency (lm/W): 30
Photosynthetic Photon Flux Density (μmol/㎡·s): 19±5
What is Pseudomonas sp. PSB-S?
Pseudomonas sp. PSB-S is a bacterium belonging to the Pseudomonas genus, widely found in natural environments, particularly in organic-rich areas such as wetlands, marshes, and soils. It is a Gram-negative, single-celled, motile bacterium with a strong metabolic diversity and adaptability.
Key Characteristics:
1. Ecological Distribution: Pseudomonas sp. PSB-S is primarily found in wetlands, marshes, soils, and water environments. It can survive under various environmental conditions, demonstrating strong environmental adaptability.
2. Metabolic Properties: PSB-S can utilize a wide range of organic compounds as carbon sources. It has strong decomposition abilities and can break down complex organic substances, such as polycyclic aromatic hydrocarbons and petroleum pollutants. This gives it great potential for pollutant degradation and environmental remediation.
3. Biological Functions:
Nitrogen Fixation: Some strains of PSB-S can fix nitrogen, converting atmospheric nitrogen into a form that plants can absorb.
Plant Growth Promotion: PSB-S can secrete plant growth hormones, such as auxins, which promote root development and improve the plant growth environment.
Disease Resistance: PSB-S inhibits the growth of pathogenic microbes, reducing the occurrence of plant diseases and enhancing the plant's resistance to stress.
Applications of Pseudomonas sp. PSB-S
1. Agriculture: Used as a bio-fertilizer and plant growth promoter to enhance crop yield and disease resistance.
2. Environmental Remediation: Applied in the biological remediation of contaminated soils and water, helping to degrade harmful organic pollutants and remove heavy metals.
3. Water Treatment: In aquaculture, used to improve water quality by reducing harmful substances in the water, such as ammonia nitrogen and nitrites.
What is Pseudomonas sp. PSB-S?
Pseudomonas sp. PSB-S is a bacterium belonging to the Pseudomonas genus, widely found in natural environments, particularly in organic-rich areas such as wetlands, marshes, and soils. It is a Gram-negative, single-celled, motile bacterium with a strong metabolic diversity and adaptability.
Key Characteristics:
1. Ecological Distribution: Pseudomonas sp. PSB-S is primarily found in wetlands, marshes, soils, and water environments. It can survive under various environmental conditions, demonstrating strong environmental adaptability.
2. Metabolic Properties: PSB-S can utilize a wide range of organic compounds as carbon sources. It has strong decomposition abilities and can break down complex organic substances, such as polycyclic aromatic hydrocarbons and petroleum pollutants. This gives it great potential for pollutant degradation and environmental remediation.
3. Biological Functions:
Nitrogen Fixation: Some strains of PSB-S can fix nitrogen, converting atmospheric nitrogen into a form that plants can absorb.
Plant Growth Promotion: PSB-S can secrete plant growth hormones, such as auxins, which promote root development and improve the plant growth environment.
Disease Resistance: PSB-S inhibits the growth of pathogenic microbes, reducing the occurrence of plant diseases and enhancing the plant's resistance to stress.
Applications of Pseudomonas sp. PSB-S
1. Agriculture: Used as a bio-fertilizer and plant growth promoter to enhance crop yield and disease resistance.
2. Environmental Remediation: Applied in the biological remediation of contaminated soils and water, helping to degrade harmful organic pollutants and remove heavy metals.
3. Water Treatment: In aquaculture, used to improve water quality by reducing harmful substances in the water, such as ammonia nitrogen and nitrites.