 |
|
New 'near-field' radiation therapy promises relief for overheating laptops
April 14, 2009New cooling method dissipates heat by overcoming low rate of thermal coupling between carbon nanotubes and substrate
Our modern age has become accustomed to regular improvements in information technology, says Slava Rotkin, but these advances do not come without a cost.
Take the laptop, for example. Its components, especially its billions of semiconductor electronic circuits, are growing ever tinier while the instrument's power and capacity increase. But heat generated by electric current can cause the circuits to melt and the laptop hardware to fail.
Indeed, says Rotkin, an assistant professor of physics, a laptop in use can generate heat faster than an everyday hotplate and almost as fast as a small nuclear reactor.
Developing better methods to dissipate this heat has been listed as a "grand challenge" for modern electronics by the International Technology Roadmap for Semiconductors (ITRS) , a consortium of semiconductor manufacturers.
Rotkin and his colleagues at IBM's T.J. Watson Research Center and at the Ioffe Institute in St. Petersburg, Russia, have developed a heat-dissipation method that cools carbon nanotube electronics by utilizing nonconventional radiation in a "near-field zone" just above the substrate, or surface, on which the nanotubes rest.
The new cooling method requires that the nanotubes' substrate be composed of a polar material such as silicon-dioxide (SiO2), says Rotkin. The method channels excess heat from the nanotubes into the substrate which, being much larger, can be more effectively cooled by the vents that push cool air through laptops.
"Other methods of heat dissipation do not succeed at discharging heat from within the channel of the nanotube or nanowire," says Rotkin. "Our method enables the heat to leave the channel and move to the substrate, while also scattering the hot electrons. This constitutes a novel cooling mechanism without any moving parts or cooling agents."
Rotkin and his colleagues described the results of their research in an article published in March in Nano Letters, one of the premier international journals in the field of nanotechnology.
The article, titled "An Essential Mechanism of Heat Dissipation in Carbon Nanotube Electronics," was coauthored by Rotkin, who is a primary faculty member with Lehigh's Center for Advanced Materials and Nanotechnology; Vasilii Perebeinos and Phaedon Avouris of IBM's T.J. Watson Research Center; and Alexey G. Petrov of the Ioffe Institute.
Rotkin and his colleagues have been studying the heat-dissipation problems associated with carbon nanotube electronics for three years. Their current article is the fifth coauthored by Rotkin that Nano Letters has published in the past year.
Because the nanotubes and substrate are made of heterogeneous materials, says Rotkin, their rate of thermal coupling, or heat release, is relatively low, similar to that of dry wood. This makes it difficult to dissipate heat from the nanotubes to the substrate through classical thermal conduction.
Rotkin and his colleagues instead utilize what they call surface phonon-polariton (SPP) thermal coupling by exploiting the high level of electron scattering that occurs in non-suspended carbon nanotube transistors.
A wave called a surface polariton is caused by this electron scattering, says Rotkin. This polariton is particularly strong in the near field zone just above the substrate on which the carbon nanotubes rest.
"If you put a graphene monolayer, or layer of carbon nanotubes, in a near field zone," says Rotkin, "this enables the hot electrons to be scattered by the surface polariton and to give out energy to the substrate. Heat is dissipated into the substrate as radiation tunnels from the nanotube through the near field zone to the substrate.
"If you move the nanotube away from the substrate, the near field tunneling ceases and the mechanism is absent.
"We achieve all of our coupling through surface polariton scattering because of a large enhancement of the electrical field of the polariton in the near field zone.
"Most semiconductor devices fabricated now have the nanotube or nanowire placed directly on a silica substrate, which is polar. With this mechanism, if the substrate is polar and if there's a small van der Waals gap, our new near-field channel totally dominates thermal coupling."
A change advocated by ITRS - from a silica substrate to one made of dielectric materials with a higher dielectric constant - would give the substrate material an even stronger surface polariton, says Rotkin.
Rotkin's group used microscopic quantum models to calculate heat dissipation as a function of electric field, doping and temperature.
"Most of the energy losses are dissipated directly into the polar substrate and do not contribute to the field-effect transistor temperature rise," the group wrote in the most recent Nano Letters article.
"We have shown that SPP thermal coupling increases the effective thermal conductance over the interface between nanotube and [polar substrate] by an order of magnitude."
Rotkin will summarize his research in an invited talk titled "Thermal Moore's law and near-field thermal conductance in carbon-based electronics" to be presented in August at SPIE's Optics + Photonics conference in San Diego, Calif. SPIE is an international organization devoted to light-based research.
Lehigh University
Indeed, says Rotkin, an assistant professor of physics, a laptop in use can generate heat faster than an everyday hotplate and almost as fast as a small nuclear reactor.
Developing better methods to dissipate this heat has been listed as a "grand challenge" for modern electronics by the International Technology Roadmap for Semiconductors (ITRS) , a consortium of semiconductor manufacturers.
Rotkin and his colleagues at IBM's T.J. Watson Research Center and at the Ioffe Institute in St. Petersburg, Russia, have developed a heat-dissipation method that cools carbon nanotube electronics by utilizing nonconventional radiation in a "near-field zone" just above the substrate, or surface, on which the nanotubes rest.
The new cooling method requires that the nanotubes' substrate be composed of a polar material such as silicon-dioxide (SiO2), says Rotkin. The method channels excess heat from the nanotubes into the substrate which, being much larger, can be more effectively cooled by the vents that push cool air through laptops.
"Other methods of heat dissipation do not succeed at discharging heat from within the channel of the nanotube or nanowire," says Rotkin. "Our method enables the heat to leave the channel and move to the substrate, while also scattering the hot electrons. This constitutes a novel cooling mechanism without any moving parts or cooling agents."
Rotkin and his colleagues described the results of their research in an article published in March in Nano Letters, one of the premier international journals in the field of nanotechnology.
The article, titled "An Essential Mechanism of Heat Dissipation in Carbon Nanotube Electronics," was coauthored by Rotkin, who is a primary faculty member with Lehigh's Center for Advanced Materials and Nanotechnology; Vasilii Perebeinos and Phaedon Avouris of IBM's T.J. Watson Research Center; and Alexey G. Petrov of the Ioffe Institute.
Rotkin and his colleagues have been studying the heat-dissipation problems associated with carbon nanotube electronics for three years. Their current article is the fifth coauthored by Rotkin that Nano Letters has published in the past year.
Because the nanotubes and substrate are made of heterogeneous materials, says Rotkin, their rate of thermal coupling, or heat release, is relatively low, similar to that of dry wood. This makes it difficult to dissipate heat from the nanotubes to the substrate through classical thermal conduction.
Rotkin and his colleagues instead utilize what they call surface phonon-polariton (SPP) thermal coupling by exploiting the high level of electron scattering that occurs in non-suspended carbon nanotube transistors.
A wave called a surface polariton is caused by this electron scattering, says Rotkin. This polariton is particularly strong in the near field zone just above the substrate on which the carbon nanotubes rest.
"If you put a graphene monolayer, or layer of carbon nanotubes, in a near field zone," says Rotkin, "this enables the hot electrons to be scattered by the surface polariton and to give out energy to the substrate. Heat is dissipated into the substrate as radiation tunnels from the nanotube through the near field zone to the substrate.
"If you move the nanotube away from the substrate, the near field tunneling ceases and the mechanism is absent.
"We achieve all of our coupling through surface polariton scattering because of a large enhancement of the electrical field of the polariton in the near field zone.
"Most semiconductor devices fabricated now have the nanotube or nanowire placed directly on a silica substrate, which is polar. With this mechanism, if the substrate is polar and if there's a small van der Waals gap, our new near-field channel totally dominates thermal coupling."
A change advocated by ITRS - from a silica substrate to one made of dielectric materials with a higher dielectric constant - would give the substrate material an even stronger surface polariton, says Rotkin.
Rotkin's group used microscopic quantum models to calculate heat dissipation as a function of electric field, doping and temperature.
"Most of the energy losses are dissipated directly into the polar substrate and do not contribute to the field-effect transistor temperature rise," the group wrote in the most recent Nano Letters article.
"We have shown that SPP thermal coupling increases the effective thermal conductance over the interface between nanotube and [polar substrate] by an order of magnitude."
Rotkin will summarize his research in an invited talk titled "Thermal Moore's law and near-field thermal conductance in carbon-based electronics" to be presented in August at SPIE's Optics + Photonics conference in San Diego, Calif. SPIE is an international organization devoted to light-based research.
Lehigh University
Radiation Therapy Current Events and Radiation Therapy News RSSASTRO publishes supplement on protecting cancer patients by reducing radiation doses, side effects
The Quantitative Analysis of Normal Tissue Effects in the Clinic (QUANTEC) review has been published in the International Journal of Radiation Oncology*Biology*Physics, the official journal of the American Society for Radiation Oncology (ASTRO) to update recommendations for the safe irradiation of 16 organs.
Nurses' Research Settles a Common Cancer Concern: Skin Care
Given the complexity of cancer treatment, skin care may seem like a small matter. However, a nurse at the James P. Wilmot Cancer Center knew that skin issues were a constant source of anxiety for many patients receiving radiation therapy, and through research she discovered that routine advice was rooted in myth instead of scientific evidence.
SBRT eliminates tumors with promising survival for early-stage inoperable lung cancer patients
Highly-focused stereotactic body radiation therapy (SBRT) can eliminate the targeted tumor while avoiding treatment-related illness and may ultimately improve survival for patients with inoperable non-small cell lung cancer, according to early findings of a Radiation Therapy Oncology Group study published in the March 17 cancer-themed issue of the Journal of the American Medical Association.
Age, gender can affect risk to radiation treatment
Doctors have a clearer picture than ever before of how much radiation reaches sensitive tissues during routine X-rays and similar imaging, thanks to sophisticated models of the human body being developed at the University of Florida.
Researchers discover brain tumor's 'grow-or-go' switch
Cancer cells in rapidly growing brain tumors must adjust to periods of low energy or die. When energy levels are high, tumor cells grow and proliferate. When levels are low, the cells grow less and migrate more.
Dietary supplements discouraged for prostate cancer patients
Prostate-specific dietary supplements should not be taken during radiation therapy treatments because they have been shown to increase the radiosensitivity of normal prostate cell lines, leading to normal tissue complications, according to a study in the March issue of the International Journal of Radiation Oncology*Biology*Physics, the official journal of the American Society for Radiation Oncology (ASTRO).
Long waits for radiotherapy linked to increased recurrence of breast cancer
The longer women wait for radiotherapy after breast cancer surgery, the more chance there is of local recurrence, concludes a study published on bmj.com today.
Testosterone deficiency affects male cancer survivors' quality of life
A new study has found that many male cancer survivors who develop testosterone deficiency after receiving chemotherapy or radiation therapy have an impaired quality of life and reduced energy levels.
Short-term radiation therapy successful on breast cancer
An intense three-week course of radiation therapy is just as effective as the standard five-week regimen for women with early-stage breast cancer.
Predicting prognosis and treatment response in a subset of pancreatic cancer patients
Specific chemical modifications to proteins called histones, which are found in the nucleus of cells and act as spools around which DNA is wound, can be used to predict prognosis and response to treatment in subsets patients with pancreatic cancer.
More Radiation Therapy Current Events and Radiation Therapy News Articles
 |
Principles and Practice of Radiation Therapy by Charles M. Washington MBA RT(T) FASRT (Author), Dennis T. Leaver MS RT(R)(T) FASRT (Author) Learn everything you need to know about radiation therapy with the only comprehensive text written for radiation therapy students by radiation therapists. Principles and Practice of Radiation Therapy is designed to help you understand cancer management, improve clinical techniques for delivering doses of radiation, and apply complex concepts to treatment planning and delivery. This edition features enhanced learning tools and thoroughly updated content, including three new chapters to inform you of increasingly important technologies and practices. The up-to-date and authoritative coverage of this text make it a resource you'll want to consult throughout your radiation therapy courses and beyond. Complete coverage of radiation therapy provides all introductory content plus the full... |
 |
The Physics of Radiation Therapy by Faiz M Khan (Author) Dr. Khan's classic textbook on radiation oncology physics is now in its thoroughly revised and updated Fourth Edition. It provides the entire radiation therapy team--radiation oncologists, medical physicists, dosimetrists, and radiation therapists--with a thorough understanding of the physics and practical clinical applications of advanced radiation therapy technologies, including 3D-CRT, stereotactic radiotherapy, HDR, IMRT, IGRT, and proton beam therapy. These technologies are discussed along with the physical concepts underlying treatment planning, treatment delivery, and dosimetry. This Fourth Edition includes brand-new chapters on image-guided radiation therapy (IGRT) and proton beam therapy. Other chapters have been revised to incorporate the most recent developments in the field.... |
 |
Radiation Therapy Planning by Gunilla Bentel (Author) All new expanded edition provides step-by-step guidelines on performing the technical aspects of radiation therapy. Important new coverage includes treatment preparation, 3-D treatment planning, dosimetry, new technologies, documentation, and quality assurance. In addition, you'll find added treatment planning guidelines by body region, and an expanded art program including many new 4-color illustrations. |
 |
The Best News About Radiation Therapy: Everything You Need to Know About Your Treatment by Carol Kornmehl (Author) Dr. Carol Kornmehl guides patients through this intimidating process, explaining each step of the therapy and the results they can expect from there treatment. |
 |
Radiation Therapy Physics by William R. Hendee (Author), Geoffrey S. Ibbott (Author), Eric G. Hendee (Author) The techniques of state-of-the-art radiation therapy have evolved greatly in recent years. Treatment procedures such as conformal and intensity-modulated radiation therapy, high dose-rate and brachytherapy, and image-guided radiation therapy have become standards in radiation therapy clinics around the world. Teaching models for radiation therapy have advanced accordingly, as have the protocols for calibrating and applying radiation beams in treatment. This Third Edition of Radiation Therapy Physics provides the latest information on the technological and conceptual developments currently transforming the field. A concise guide to fundamental principles and clinical applications, the text includes reviews of the most up-to-date instrumentation as well as critical historical links. ... |
 |
Radiation Oncology: An Evidence-Based Approach (Medical Radiology / Radiation Oncology) by Jiade J. Lu (Editor), Jiade J. Lu (Editor), Luther W. Brady (Editor), Luther W. Brady (Editor), Luther W. Brady (Editor), Hans-Peter Heilmann (Editor), Michael Molls (Editor), Carsten Nieder (Editor) Radiation Oncology: An Evidence-Based Approach (ROEBA) is a reference book designed to enable radiation oncologists, including those in training, to make diagnostic and treatment decisions on the basis of the best available scientific evidence. Ease of use is ensured by a structured, reader-friendly format that offers rapid access to evidence-based recommendations. ROEBA’s orientation is entirely practical, in that the focus is solely on diagnostic/staging and treatment issues. Detailed diagnostic and therapeutic guidelines are provided for multidisciplinary cancer management as well as radiation therapy techniques. The evidence underlying each recommendation is clearly and concisely explained, and the strength of the recommendations and evidence is systemically graded. Furthermore,... |
 |
Coping With Chemotherapy and Radiation Therapy: Everything You Need to Know by Daniel Cukier (Author) New advances in treatment offer cancer patients more options than ever before Coping with Chemotherapy and Radiation is an accessible, accurate guide to the latest developments in radiation therapy and chemotherapy. You will find important information on how chemotherapy and radiation treatments work; what to expect from treatments, how to alleviate common side effects, and more. |
 |
A Guide for Delineation of Lymph Nodal Clinical Target Volume in Radiation Therapy by G. Ausili Cefaro (Author), C. A. Perez (Contributor), D. Genovesi (Contributor), A. Vinciguerra (Contributor) Conformal radiotherapy offers the opportunity to enhance precise delivery of high dose radiation to the target volume while maintaining normal tissues doses at acceptable tolerance levels. This technique requires an exact definition of the treatment volumes: gross tumour volume (GTV), clinical target volume (CTV) and planning target volume (PTV). For this reason, it is important to have a very good knowledge of radiological anatomy and natural history of the disease. In particular, CTV is a tissue volume that contains the macroscopic disease with the surrounding areas suspected of subclinical involvement (CTV) and regional lymph nodes (CTV2). Delivery of adequate doses of irradiation to lymph nodes at risk, enhances treatment outcome and selective irradiation of them decreases... |
|
Portal Design in Radiation Therapy, 2nd ed by Byron G. Dasher; Anne Marie Vann (Author), K Van Sickle and P Markwalter (Illustrator) Portal Design in Radiation Therapy, 2nd Edition contains over 120 explicit diagrams illustrating the anatomy and lymphatics included in typical treatment portals. In addition, CT and MR anatomy are included, as well as tissue tolerance charts. Descriptions of surrounding anatomy, routes of spread, technical aspects of portal design and typical doses employed for each tumor site are provided. | |
 |
Radx Radiation Therapy Moisture Therapy Cream, 2 oz. by SolRx Get relief from the effects of radiation therapy with the Radx line of non-prescription skin care products from SolRx. They have been tested in several hundred cancer treatment facilities throughout the United States with exceptional results. The moisture therapy cream contains Prickly Pear Cactus gel and reduces the damaging effects of radiation when used before treatments as well as replenishing lost moisture when used after treatments. |
| © 2010 BrightSurf.com |