Solid State Detector || Semiconductor Detector || 12th Class Physics

Are you looking for an exciting video that explains the working, construction, and uses of Solid-State Detectors for your Physics Class 12 curriculum? Look no further! In this video, we will explore the Solid-State Detector Principle and how it operates, including how it detects radiation and its various uses. We'll also discuss its construction and how its design helps to make it more sensitive to radiation detection. Solid-State Detectors use semiconducting materials like silicon and germanium, which when exposed to radiation, generate charges that can be measured. This makes them perfect for use in radiation detection applications, such as medical imaging and nuclear physics experiments. The video will also highlight the various types of solid-state detectors and how they work differently based on their materials and designs. By the end of this video, you'll have a clear understanding of how solid-state detectors work and how they are used in real-life applications. With this knowledge, you'll be better equipped to understand and appreciate the fascinating world of nuclear physics. So, don't miss this chance to learn about Solid-State Detectors, watch the video now! Solid-state detector, also called Semiconductor Radiation Detector, radiation detector in which a semiconductor material such as a silicon or germanium crystal constitutes the detecting medium. One such device consists of a p-n junction across which a pulse of current develops when a particle of ionizing radiation traverses it. In a different device, the absorption of ionizing radiation generates pairs of charge carriers (electrons and electron-deficient sites called holes) in a block of semiconducting material; the migration of these carriers under the influence of a voltage maintained between the opposite faces of the block constitutes a pulse of current. The pulses created in this way are amplified, recorded, and analyzed to determine the energy, number, or identity of the incident-charged particles. The sensitivity of these detectors is increased by operating them at low temperatures—commonly that of liquid nitrogen, −164 °C (−263 °F)—which suppresses the random formation of charge carriers by thermal vibration. #solidstatedetector #class12physics #NuclearPhysics Previous Videos GM Counter in Urdu Hindi 👉https://youtu.be/KBqEDzFkClo Wilson Cloud Chamberin Urdu Hindi 👉https://youtu.be/eQX94YfoWrI