Heterotrophic bacteria such as Cupriavidus necator can already produce PHB bioplastic. These bacteria's energy source is the sugar obtained from crops. Cyanobacteria has a significant advantage in PHB production. To conclude, microalgae can fix sunlight and extract energy from it. As a result, PHB production is CO2-neutral. Heterotrophe Bakterien wie Cupriavidus necator können bereits PHB-Biokunststoff produzieren. Die Energiequelle dieser Bakterien ist der aus Pflanzen gewon

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Heterotrophic bacteria such as Cupriavidus necator can already produce PHB bioplastic. These bacteria's energy source is the sugar obtained from crops. Cyanobacteria has a significant advantage in PHB production. To conclude, microalgae can fix sunlight and extract energy from it. As a result, PHB production is CO2-neutral. Heterotrophe Bakterien wie Cupriavidus necator können bereits PHB-Biokunststoff produzieren. Die Energiequelle dieser Bakterien ist der aus Pflanzen gewon

Heterotrophic bacteria such as Cupriavidus necator can already produce PHB bioplastic. These bacteria's energy source is the sugar obtained from crops. Cyanobacteria has a significant advantage in PHB production. To conclude, microalgae can fix sunlight and extract energy from it. As a result, PHB production is CO2-neutral. Heterotrophe Bakterien wie Cupriavidus necator können bereits PHB-Biokunststoff produzieren. Die Energiequelle dieser Bakterien ist der aus Pflanzen gewon