Radiation physics for medical physicists
Material type: TextLanguage: English Series: Graduate Texts in PhysicsPublication details: Switzerland : Springer, 2016. Edition: 3rd edDescription: lvii, 906p. : 257 illustrations, 67 illustrations in colorISBN: 9783319797816Subject(s): Medical physics | Radiation | Radiology | Biomedical engineering | Nuclear medicine | Particle acceleration | Medical and Radiation Physics | Diagnostic Radiology | Biomedical Engineering and Bioengineering | Nuclear Medicine | Particle Acceleration and Detection, Beam PhysicsDDC classification: 615.849 Online resources: Table of contents | Reviews Summary: This textbook summarizes the basic knowledge of atomic, nuclear, and radiation physics that professionals working in medical physics and biomedical engineering need for efficient and safe use of ionizing radiation in medicine. Concentrating on the underlying principles of radiation physics, the textbook covers the prerequisite knowledge for medical physics courses on the graduate and post-graduate levels in radiotherapy physics, radiation dosimetry, imaging physics, and health physics, thus providing the link between elementary undergraduate physics and the intricacies of four medical physics specialties: diagnostic radiology physics, nuclear medicine physics, radiation oncology physics, and health physics. To recognize the importance of radiation dosimetry to medical physics three new chapters have been added to the 14 chapters of the previous edition. Chapter 15 provides a general introduction to radiation dosimetry. Chapter 16 deals with absolute radiation dosimetry systems that establish absorbed dose or some other dose related quantity directly from the signal measured by the dosimeter. Three absolute dosimetry techniques are known and described in detail: (i) calorimetric; (ii) chemical (Fricke), and (iii) ionometric. Chapter 17 deals with relative radiation dosimetry systems that rely on a previous dosimeter calibration in a known radiation field. Many relative radiation dosimetry systems have been developed to date and four most important categories used routinely in medicine and radiation protection are described in this chapter: (i) Ionometric dosimetry; (ii) Luminescence dosimetry; (iii) Semiconductor dosimetry; and (iv) Film dosimetry. The book is intended as a textbook for a radiation physics course in academic medical physics graduate programs as well as a reference book for candidates preparing for certification examinations in medical physics sub-specialties. It may also be of interest to many professionals, not only physicists, who in their daily occupations deal with various aspects of medical physics or radiation physics and have a need or desire to improve their understanding of radiation physics.Item type | Current library | Call number | Status | Date due | Barcode |
---|---|---|---|---|---|
Book | CMRP Library | 615.849 POD-R (Browse shelf(Opens below)) | Available | 25229 | |
Book | CMRP Library | 615.849 POD-R (Browse shelf(Opens below)) | Available | 23577 | |
Book | CMRP Library | 615.849 POD-R (Browse shelf(Opens below)) | Available | 23578 | |
Book | CMRP Library | 615.849 POD-R (Browse shelf(Opens below)) | Checked out to Sarita Sah (CMRP231126006) | 14/09/2024 | 23579 |
Book | CMRP Library | 615.849 POD-R (Browse shelf(Opens below)) | Available | 23580 | |
Book | CMRP Library | 615.849 POD-R (Browse shelf(Opens below)) | Checked out to ARGHYAJIT PAUL (CMRP231126001) | 04/09/2024 | 23581 |
This textbook summarizes the basic knowledge of atomic, nuclear, and radiation physics that professionals working in medical physics and biomedical engineering need for efficient and safe use of ionizing radiation in medicine. Concentrating on the underlying principles of radiation physics, the textbook covers the prerequisite knowledge for medical physics courses on the graduate and post-graduate levels in radiotherapy physics, radiation dosimetry, imaging physics, and health physics, thus providing the link between elementary undergraduate physics and the intricacies of four medical physics specialties: diagnostic radiology physics, nuclear medicine physics, radiation oncology physics, and health physics. To recognize the importance of radiation dosimetry to medical physics three new chapters have been added to the 14 chapters of the previous edition. Chapter 15 provides a general introduction to radiation dosimetry. Chapter 16 deals with absolute radiation dosimetry systems that establish absorbed dose or some other dose related quantity directly from the signal measured by the dosimeter. Three absolute dosimetry techniques are known and described in detail: (i) calorimetric; (ii) chemical (Fricke), and (iii) ionometric. Chapter 17 deals with relative radiation dosimetry systems that rely on a previous dosimeter calibration in a known radiation field. Many relative radiation dosimetry systems have been developed to date and four most important categories used routinely in medicine and radiation protection are described in this chapter: (i) Ionometric dosimetry; (ii) Luminescence dosimetry; (iii) Semiconductor dosimetry; and (iv) Film dosimetry.
The book is intended as a textbook for a radiation physics course in academic medical physics graduate programs as well as a reference book for candidates preparing for certification examinations in medical physics sub-specialties. It may also be of interest to many professionals, not only physicists, who in their daily occupations deal with various aspects of medical physics or radiation physics and have a need or desire to improve their understanding of radiation physics.
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