100 Examples of sentences containing the common noun "pyrolysis"

Definition

Pyrolysis is the thermal decomposition of materials at elevated temperatures in an inert atmosphere, typically in the absence of oxygen. It is commonly used in the processing of organic materials, such as biomass, plastics, and tires, to convert them into usable energy forms, such as gases, oils, and char.

Synonyms

• Thermal decomposition
• Destructive distillation
• Carbonization
• Gasification (in certain contexts)

Antonyms

• Combustion
• Oxidation
• Incineration

Examples

1. Researchers are studying how pyrolysis can effectively convert waste into energy.
2. The pyrolysis process reduces the volume of organic waste significantly.
3. Many industries utilize pyrolysis to recycle plastics into usable products.
4. The efficiency of pyrolysis depends on the temperature and feedstock used.
5. During pyrolysis, materials break down into solid, liquid, and gaseous products.
6. Scientists have developed new methods to enhance pyrolysis efficiency.
7. The pyrolysis of biomass can be a sustainable energy solution.
8. After pyrolysis, the remaining char can be used as a soil amendment.
9. The latest technology in pyrolysis allows for real-time monitoring of the process.
10. Pyrolysis can help mitigate landfill waste by converting it into valuable resources.
11. The byproducts of pyrolysis can be used in various industrial applications.
12. The pyrolysis temperature needs to be optimized for different feedstocks.
13. A pilot plant is being built to test large-scale pyrolysis applications.
14. Pyrolysis can transform rubber tires into oil and carbon black.
15. The pyrolysis of organic matter releases volatile compounds.
16. Understanding the kinetics of pyrolysis is crucial for process design.
17. The environmental impact of pyrolysis is generally lower than incineration.
18. Pyrolysis can be an effective way to produce renewable fuels.
19. The research team analyzed the pyrolysis products for toxicity.
20. Waste-to-energy facilities often incorporate pyrolysis technologies.
21. The pyrolysis process can be integrated with other waste management strategies.
22. Engineers are exploring ways to improve the scalability of pyrolysis.
23. Pyrolysis systems can operate continuously or batch-wise.
24. The pyrolysis of agricultural residues can yield biochar.
25. Studies have shown that pyrolysis can reduce greenhouse gas emissions.
26. The pyrolysis reaction is endothermic and requires heat input.
27. Different catalysts can be used to enhance pyrolysis reactions.
28. The pyrolysis of plastics generates valuable hydrocarbons.
29. Safety measures are essential during the pyrolysis process.
30. The pyrolysis of lignocellulosic biomass produces bio-oil.
31. Pyrolysis can contribute to a circular economy by recycling materials.
32. Companies are investing in pyrolysis technology for waste management.
33. The pyrolysis of coal can produce synthetic gas.
34. The efficiency of pyrolysis can be affected by moisture content.
35. Pyrolysis plants can be designed to handle various types of feedstock.
36. Understanding the mechanisms of pyrolysis is critical for optimization.
37. The pyrolysis of food waste can create biogas.
38. The pyrolysis output can vary based on the heating rate.
39. Many researchers are focused on the pyrolysis of municipal solid waste.
40. Pyrolysis can also be used to treat contaminated soils.
41. The pyrolysis of fish waste can yield fish oil and meal.
42. Byproducts from pyrolysis can be utilized in other industrial processes.
43. The pyrolysis technology can be adapted for small-scale operations.
44. Innovative pyrolysis techniques are being explored for energy recovery.
45. The future of pyrolysis looks promising with advancements in technology.
46. Pyrolysis can be a feasible option for developing countries to manage waste.
47. The pyrolysis of plastics helps reduce ocean pollution.
48. Pyrolysis char can serve as a carbon sink in agriculture.
49. The pyrolysis industry is gaining traction as sustainability becomes a priority.
50. The pyrolysis method is different from traditional combustion processes.
51. A detailed study on pyrolysis kinetics was published last month.
52. The pyrolysis of wood chips can produce biofuels.
53. Many startups are focusing on pyrolysis as a solution for plastic waste.
54. Pyrolysis requires specific reactor designs to optimize product yield.
55. The history of pyrolysis dates back centuries in various forms.
56. The pyrolysis of textiles can recover fibers and other valuable materials.
57. Understanding the product distribution from pyrolysis is important for market applications.
58. The pyrolysis process can be tuned for specific end-products.
59. The pyrolysis of hazardous waste must be carefully controlled.
60. Enhanced pyrolysis technologies can improve the recovery of oils.
61. The pyrolysis of natural rubber can be a viable recycling option.
62. Researchers are investigating the pyrolysis of food packaging materials.
63. The pyrolysis of biomass can help reduce dependency on fossil fuels.
64. The study explored the economic viability of pyrolysis plants.
65. Pyrolysis can be combined with other thermochemical processes for efficiency.
66. The environmental benefits of pyrolysis are being increasingly recognized.
67. A conference on pyrolysis technologies attracted global experts.
68. The pyrolysis of lignin can produce phenolic compounds.
69. Many universities are conducting research on pyrolysis methods.
70. The pyrolysis process can be enhanced using microwave energy.
71. Pyrolysis can be a game-changer for managing plastic waste.
72. Pilot studies on pyrolysis have shown promising results.
73. The pyrolysis of organic waste can yield biochar for carbon sequestration.
74. Pyrolysis technology is evolving rapidly to meet global waste challenges.
75. The pyrolysis of cellulosic materials is a subject of ongoing research.
76. The pyrolysis of e-waste can recover valuable metals.
77. Companies are developing modular pyrolysis systems for flexibility.
78. The pyrolysis process can be regulated to minimize emissions.
79. The potential of pyrolysis in circular economy initiatives is being explored.
80. The pyrolysis of contaminated feedstock requires special treatment.
81. The pyrolysis of agricultural waste can support rural economies.
82. Researchers are looking into the scalability of pyrolysis technologies.
83. The pyrolysis output can be tailored to specific market demands.
84. Pyrolysis can help countries transition to sustainable energy sources.
85. The pyrolysis of hazardous materials needs stringent safety protocols.
86. Innovative approaches to pyrolysis are being developed in academia.
87. The pyrolysis process can convert organic waste into clean energy.
88. The impact of pyrolysis on climate change is being studied extensively.
89. Companies are collaborating on pyrolysis research for better technologies.
90. The pyrolysis of agricultural residues can create new revenue streams.
91. Governments are promoting pyrolysis as a waste management solution.
92. The pyrolysis of food waste reduces the need for landfills.
93. New machinery for pyrolysis is being showcased at trade shows.
94. The pyrolysis industry is expected to grow significantly in the coming years.
95. Environmental assessments of pyrolysis facilities are essential.
96. The pyrolysis of mixed waste streams poses unique challenges.
97. Public awareness of pyrolysis benefits is increasing.
98. The pyrolysis of biomass can be a key player in energy transition.
99. The pyrolysis of various materials can yield different products.
100. Future innovations in pyrolysis could revolutionize waste management.