100 Examples of sentences containing the common noun "photomultiplier"

Definition

A photomultiplier is a type of electronic device that converts light (photons) into an electrical signal. It is highly sensitive and is commonly used in scientific applications such as radiation detection, medical imaging, and particle physics experiments.

Synonyms

• Light detector
• Photon detector
• Radiation detector

Antonyms

• Light blocker
• Light absorber
• Non-detection device

Examples

1. The scientist used a photomultiplier to measure the faint light emitted by the sample.
2. In the lab, the team relied on the photomultiplier to enhance their data collection.
3. The photomultiplier was crucial for detecting the low levels of radiation.
4. Researchers often choose a photomultiplier for its exceptional sensitivity.
5. The photomultiplier allowed them to observe phenomena that were previously undetectable.
6. They calibrated the photomultiplier to ensure accurate readings.
7. The device’s efficiency made the photomultiplier an essential tool in the experiment.
8. The photomultiplier responded quickly to changes in light intensity.
9. Using a photomultiplier, the team could analyze the light spectrum emitted by the sample.
10. The photomultiplier has a wide range of applications in modern physics.
11. To measure the scintillation light, they utilized a photomultiplier.
12. The researchers were impressed by the photomultiplier's ability to detect single photons.
13. The design of the photomultiplier has evolved significantly over the years.
14. In high-energy physics, the photomultiplier plays a vital role in data acquisition.
15. The photomultiplier is often used in conjunction with other detection equipment.
16. They replaced the old model with a newer photomultiplier for better performance.
17. The sensitivity of the photomultiplier was key to the success of the project.
18. They observed that the photomultiplier had a response time of just a few nanoseconds.
19. The photomultiplier detected even the slightest fluctuations in light.
20. During the experiment, the photomultiplier provided real-time data.
21. The research depended heavily on the accuracy of the photomultiplier readings.
22. The team was excited to see how the photomultiplier could improve their results.
23. A malfunction in the photomultiplier could lead to significant data loss.
24. The setup included a photomultiplier and several other advanced instruments.
25. By adjusting the settings on the photomultiplier, they improved its efficiency.
26. The photomultiplier was tested under various conditions to ensure reliability.
27. They learned that the photomultiplier was sensitive to temperature changes.
28. The photomultiplier was able to amplify the signal from the light source significantly.
29. The complexity of the photomultiplier fascinates many engineers.
30. The performance of the photomultiplier was beyond their expectations.
31. They conducted experiments to determine the optimal placement of the photomultiplier.
32. The photomultiplier successfully detected the ultraviolet light emitted from the source.
33. The researchers struggled with the calibration of the photomultiplier.
34. The photomultiplier played a crucial role in their groundbreaking findings.
35. They documented every reading from the photomultiplier for further analysis.
36. The photomultiplier enabled them to visualize the data in real-time.
37. A thorough understanding of the photomultiplier is essential for its proper use.
38. The team discussed the advantages of using a photomultiplier over traditional sensors.
39. They designed an experiment specifically to test the limits of the photomultiplier.
40. The photomultiplier was critical in identifying rare events in the data.
41. Without the photomultiplier, many discoveries would not have been possible.
42. The research paper highlighted the importance of the photomultiplier in their methodology.
43. The team was trained to operate the photomultiplier safely and effectively.
44. They compared the output of the photomultiplier with other detection methods.
45. The photomultiplier proved to be a reliable source of data throughout the study.
46. The team celebrated when the photomultiplier finally yielded clear results.
47. The configuration of the photomultiplier was optimized for maximum output.
48. They found that the photomultiplier had a linear response to varying light levels.
49. The photomultiplier's performance was a highlight of the conference presentation.
50. They included a detailed analysis of the photomultiplier in their report.
51. The photomultiplier successfully detected faint signals in the background noise.
52. Their experiments with the photomultiplier opened new avenues for research.
53. The photomultiplier operated best under controlled lighting conditions.
54. The sensitivity range of the photomultiplier exceeded their expectations.
55. The photomultiplier's ability to amplify signals made it indispensable.
56. They noted a significant improvement in data quality with the new photomultiplier.
57. The team was impressed by the compact size of the latest photomultiplier model.
58. The photomultiplier's response curve was crucial for understanding its behavior.
59. They calibrated the photomultiplier to minimize background interference.
60. The photomultiplier enabled them to detect light levels that were previously unreachable.
61. The engineer explained how to troubleshoot common issues with the photomultiplier.
62. The photomultiplier was integrated into the larger experimental setup.
63. The results from the photomultiplier were consistent across multiple trials.
64. They detailed the specifications of the photomultiplier in the grant application.
65. The photomultiplier enhanced their ability to conduct sensitive measurements.
66. They were pleased with the performance of the photomultiplier during the tests.
67. The photomultiplier was connected to a data acquisition system for analysis.
68. The research focused on improving the efficiency of the photomultiplier.
69. The team relied on the photomultiplier for precise light measurements.
70. The photomultiplier was a key component in their detection system.
71. They found that the photomultiplier could operate in a wide temperature range.
72. The photomultiplier's design allows for quick replacements in the field.
73. They were excited to publish their findings that involved the photomultiplier.
74. The photomultiplier was instrumental in capturing transient events.
75. They discovered that the photomultiplier had a longer lifespan than expected.
76. The photomultiplier provided essential data for their theoretical models.
77. During the experiment, the photomultiplier showed a remarkable degree of stability.
78. They consulted the manual to understand the photomultiplier settings.
79. The photomultiplier's ability to work in low-light conditions was noteworthy.
80. The research team held a seminar on the applications of the photomultiplier.
81. They were surprised by the photomultiplier's low noise levels.
82. The photomultiplier detected signals that were previously thought to be impossible.
83. The data collected by the photomultiplier was used for multiple studies.
84. They discussed potential improvements for the photomultiplier technology.
85. The photomultiplier was essential for their time-resolved experiments.
86. The calibration of the photomultiplier was a meticulous process.
87. They had to replace the photomultiplier after several years of use.
88. The photomultiplier enabled them to push the boundaries of their research.
89. They integrated the photomultiplier with software for better data visualization.
90. The photomultiplier's output was affected by ambient light conditions.
91. They used a photomultiplier to track the decay of the radioactive sample.
92. The photomultiplier was a focal point in their experimental design.
93. The research highlighted the versatility of the photomultiplier in different fields.
94. They conducted a training session on how to operate the photomultiplier.
95. The photomultiplier's sensitivity made it ideal for their specific application.
96. They noticed that the photomultiplier responded differently in varying environments.
97. The photomultiplier was recognized for its contributions to scientific advancement.
98. They sought funding to acquire a more advanced photomultiplier.
99. The photomultiplier provided critical evidence for their hypothesis.
100. The performance metrics of the photomultiplier were impressive compared to older models.