你的描述比较宽泛,投文章是要根据你做的具体的研究来的。建议你看一下这一领域里主流杂志发表的文章的参考文献,就基本能了解该领域大概有哪些杂志可供你选择。
2008年SCI收录期刊影响因子(按字顺排列) Abbreviated Journal Title ISSN 2008 Impact Immediacy 2008 Cited Total Cites Factor Index Articles Half-life AAPG BULL 0149-1423 4588 364 353 68 >0 AAPS PHARMSCITECH 1530-9932 1078 445 090 167 4 AATCC REV 1532-8813 252 352 091 44 5 ABDOM IMAGING 0942-8925 2122 485 387 124 6 ABH MATH SEM HAMBURG 0025-5858 318 086 000 7 >0 ABSTR APPL ANAL 1085-3375 283 644 533 60 9 ACAD EMERG MED 1069-6563 4406 460 433 187 7 ACAD MED 1040-2446 5422 867 8 ACAD RADIOL 1076-6332 3027 021 407 167 5 ACCOUNTS CHEM RES 0001-4842 26252 176 683 167 7 ACCREDIT QUAL ASSUR 0949-1775 473 781 275 80 6 ACI MATER J 0889-325X 1672 568 083 72 >0 ACI STRUCT J 0889-3241 1929 895 167 72 7 ACM COMPUT SURV 0360-0300 3273 920 167 12 1 ACM SIGPLAN NOTICES 0362-1340 846 163 013 228 9 ACM T COMPUT LOG 1529-3785 374 766 276 29 4 ACM T COMPUT SYST 0734-2071 1069 391 500 10 >0 ACM T DATABASE SYST 0362-5915 1404 613 074 27 >0 ACM T DES AUTOMAT EL 1084-4309 407 848 098 61 4 ACM T GRAPHIC 0730-0301 4083 383 150 107 7 ACM T INFORM SYST 1046-8188 1455 472 174 23 7 ACM T MATH SOFTWARE 0098-3500 2111 197 526 38 >0 ACM T MODEL COMPUT S 1049-3301 437 029 050 20 >0 ACM T MULTIM COMPUT 1551-6857 155 465 037 27 6 ACM T PROGR LANG SYS 0164-0925 1500 444 051 39 >0 ACM T SOFTW ENG METH 1049-331X 729 958 261 23 8 ACOUST PHYS+ 1063-7710 531 622 125 112 6 ACS CHEM BIOL 1554-8929 867 149 351 77 8 ACS NANO 1936-0851 703 472 389 296 9 ACSMS HEALTH FIT J 1091-5397 63 353 042 24 ACTA ACUST UNITED AC 1610-1928 1473 538 080 100 >0 ACTA AGR SCAND A-AN 0906-4702 393 489 088 34 3 ACTA AGR SCAND B-S P 0906-4710 262 407 176 51 8 ACTA ALIMENT HUNG 0139-3006 319 441 000 43 4 ACTA ANAESTH SCAND 0001-5172 4842 953 503 199 1 ACTA APPL MATH 0167-8019 788 430 218 87 2 ACTA ARITH 0065-1036 1184 467 114 44 >0 ACTA ASTRONAUT 0094-5765 1212 374 013 231 6 ACTA ASTRONOM 0001-5237 860 778 700 30 3 ACTA BIOCH BIOPH SIN 1672-9145 825 086 163 123 8 ACTA BIOCHIM POL 0001-527X 1655 448 237 93 4 ACTA BIOL CRACOV BOT 0001-5296 142 351 000 13 5 ACTA BIOL HUNG 0236-5383 371 619 067 75 2 ACTA BIOMATER 1742-7061 1176 727 491 216 3 ACTA BIOQUIM CLIN L 0325-2957 39 044 077 13 ACTA BIOTHEOR 0001-5342 423 735 056 18 >0 ACTA BOT GALLICA 1253-8078 125 145 020 49 >0 ACTA CARDIOL 0001-5385 621 581 096 104 8 ACTA CHIM SINICA 0567-7351 2339 682 067 461 5 ACTA CHIM SLOV 1318-0207 586 909 109 101 9 ACTA CHIR BELG 0001-5458 729 474 060 167 1 ACTA CHIROPTEROL 1508-1109 290 825 026 38 8 ACTA CHROMATOGR 1233-2356 162 621 111 54 5 ACTA CLIN BELG 0001-5512 528 282 054 56 4 ACTA CRYSTALLOGR A 0108-7673 11622 051 556 72 >0 ACTA CRYSTALLOGR B 0108-7681 10332 341 419 86 >0 ACTA CRYSTALLOGR C 0108-2701 6119 561 354 328 >0 ACTA CRYSTALLOGR D 0907-4449 9365 943 581 148 7 ACTA CRYSTALLOGR E 1600-5368 7113 367 293 3533 4 ACTA CRYSTALLOGR F 1744-3091 586 606 195 293 3 ACTA CYTOL 0001-5547 2713 835 093 118 >0 ACTA DERM-VENEREOL 0001-5555 3545 456 284 74 >0 ACTA DIABETOL 0940-5429 839 926 121 33 8 ACTA ENDOSC 0240-642X 62 074 028 72 ACTA ETHOL 0873-9749 174 667 071 14 4 ACTA GASTRO-ENT BELG 0001-5644 425 832 114 35 1 ACTA GEOL POL 0001-5709 415 581 167 42 >0 ACTA GEOL SIN-ENGL 1000-9515 1312 431 153 118 7 ACTA GEOPHYS 1895-6572 157 308 222 63 1 ACTA HAEMATOL-BASEL 0001-5792 1582 191 061 82 2 ACTA HISTOCHEM 0065-1281 719 101 298 57 9 ACTA HISTOCHEM CYTOC 0044-5991 221 857 048 21 5 ACTA HYDROCH HYDROB 0323-4320 486 907 0 5 ACTA INFORM 0001-5903 734 789 286 21 >0 ACTA MATER 1359-6454 23367 729 542 612 7 ACTA MATH HUNG 0236-5294 961 317 077 104 >0 ACTA MATH SCI 0252-9602 301 222 000 99 6 ACTA MATH SIN 1439-8516 961 543 050 179 7 ACTA MATH-DJURSHOLM 0001-5962 2425 143 273 11 >0 ACTA MECH 0001-5970 1956 297 189 127 9 ACTA MECH SINICA 0567-7718 606 939 122 74 2 ACTA MECH SOLIDA SIN 0894-9166 263 552 043 70 7 ACTA MED OKAYAMA 0386-300X 478 969 127 55 8 ACTA METALL SIN 0412-1961 975 474 075 268 4 您可以查下,去影响因子网,实在是太多了,而且还有年限,也不知道你要哪年的,这里有2001-2009年sci目录查下
可以这样说:Zhang D Basic Ultrasonic M Beijing: Science Publisher, 希望能帮到你,满意请采纳,别忘了点个赞!
Introduction vibrations of frequencies greater than the upper limit of the audible range for humans—that is, greater than about 20 The term sonic is applied to ultrasound waves of very high Hypersound, sometimes called praetersound or microsound, is sound waves of frequencies greater than 1013 At such high frequencies it is very difficult for a sound wave to propagate efficiently; indeed, above a frequency of about 25 × 1013 hertz, it is impossible for longitudinal waves to propagate at all, even in a liquid or a solid, because the molecules of the material in which the waves are traveling cannot pass the vibration along rapidly TableMany animals have the ability to hear sounds in the human ultrasonic frequency Some ranges of hearing for mammals and insects are compared with those of humans in the T A presumed sensitivity of roaches and rodents to frequencies in the 40 kilohertz region has led to the manufacture of “pest controllers” that emit loud sounds in that frequency range to drive the pests away, but they do not appear to work as Transducers An ultrasonic transducer is a device used to convert some other type of energy into an ultrasonic There are several basic types, classified by the energy source and by the medium into which the waves are being Mechanical devices include gas-driven, or pneumatic, transducers such as whistles as well as liquid-driven transducers such as hydrodynamic oscillators and vibrating These devices, limited to low ultrasonic frequencies, have a number of industrial applications, including drying, ultrasonic cleaning, and injection of fuel oil into Electromechanical transducers are far more versatile and include piezoelectric and magnetostrictive A magnetostrictive transducer makes use of a type of magnetic material in which an applied oscillating magnetic field squeezes the atoms of the material together, creating a periodic change in the length of the material and thus producing a high-frequency mechanical Magnetostrictive transducers are used primarily in the lower frequency ranges and are common in ultrasonic cleaners and ultrasonic machining By far the most popular and versatile type of ultrasonic transducer is the piezoelectric crystal, which converts an oscillating electric field applied to the crystal into a mechanical Piezoelectric crystals include quartz, Rochelle salt, and certain types of Piezoelectric transducers are readily employed over the entire frequency range and at all output Particular shapes can be chosen for particular For example, a disc shape provides a plane ultrasonic wave, while curving the radiating surface in a slightly concave or bowl shape creates an ultrasonic wave that will focus at a specific Piezoelectric and magnetostrictive transducers also are employed as ultrasonic receivers, picking up an ultrasonic vibration and converting it into an electrical Applications in research One of the important areas of scientific study in which ultrasonics has had an enormous impact is When water is boiled, bubbles form at the bottom of the container, rise in the water, and then collapse, leading to the sound of the boiling The boiling process and the resulting sounds have intrigued people since they were first observed, and they were the object of considerable research and calculation by the British physicists Osborne Reynolds and Lord Rayleigh, who applied the term cavitation to the process of formation of Because an ultrasonic wave can be used carefully to control cavitation, ultrasound has been a useful tool in the investigation of the The study of cavitation has also provided important information on intermolecular Research is being carried out on aspects of the cavitation process and its A contemporary subject of research involves emission of light as the cavity produced by a high-intensity ultrasonic wave This effect, called sonoluminescence, is believed to create instantaneous temperatures hotter than the surface of the S The speed of propagation of an ultrasonic wave is strongly dependent on the viscosity of the This property can be a useful tool in investigating the viscosity of Because the various parts of a living cell are distinguished by differing viscosities, acoustical microscopy can make use of this property of cells to “see” into living cells, as will be discussed below in Medical Ranging and navigating Sonar (sound navigation and ranging) has extensive marine By sending out pulses of sound or ultrasound and measuring the time required for the pulses to reflect off a distant object and return to the source, the location of that object can be ascertained and its motion This technique is used extensively to locate and track submarines at sea and to locate explosive mines below the surface of the Two boats at known locations can also use triangulation to locate and track a third boat or The distance over which these techniques can be used is limited by temperature gradients in the water, which bend the beam away from the surface and create shadow One of the advantages of ultrasonic waves over sound waves in underwater applications is that, because of their higher frequencies (or shorter wavelengths), the former will travel greater distances with less Ranging has also been used to map the bottom of the ocean, providing depth charts that are commonly used in navigation, particularly near coasts and in shallow Even small boats are now equipped with sonic ranging devices that determine and display the depth of the water so that the navigator can keep the boat from beaching on submerged sandbars or other shallow Modern fishing boats use ultrasonic ranging devices to locate schools of fish, substantially increasing their Even in the absence of visible light, bats can guide their flight and even locate flying insects (which they consume in flight) through the use of sonic Ultrasonic echolocation has also been used in traffic control applications and in counting and sorting items on an assembly Ultrasonic ranging provides the basis of the eye and vision systems for robots, and it has a number of important medical applications (see below) The Doppler effect If an ultrasonic wave is reflected off a moving obstacle, the frequency of the resulting wave will be changed, or Doppler- More specifically, if the obstacle is moving toward the source, the frequency of the reflected wave will be increased; and if the obstacle is moving away from the source, the frequency of the reflected wave will be The amount of the frequency shift can be used to determine the velocity of the moving Just as the Doppler shift for radar, an electromagnetic wave, can be used to determine the speed of a moving car, so can the speed of a moving submarine be determined by the Doppler shift of a sonar An important industrial application is the ultrasonic flow meter, in which reflecting ultrasound off a flowing liquid leads to a Doppler shift that is calibrated to provide the flow rate of the This technique also has been applied to blood flow in Many burglar alarms, both for home use and for use in commercial buildings, employ the ultrasonic Doppler shift Such alarms cannot be used where pets or moving curtains might activate Materials testing Nondestructive testing involves the use of ultrasonic echolocation to gather information on the integrity of mechanical Since changes in the material present an impedance mismatch from which an ultrasonic wave is reflected, ultrasonic testing can be used to identify faults, holes, cracks, or corrosion in materials, to inspect welds, to determine the quality of poured concrete, and to monitor metal Owing to the mechanism by which sound waves propagate in metals, ultrasound can be used to probe more deeply than any other form of Ultrasonic procedures are used to perform in-service inspection of structures in nuclear Structural flaws in materials can also be studied by subjecting the materials to stress and looking for acoustic emissions as the materials are Acoustic emission, the general name for this type of nondestructive study, has developed as a distinct field of High-intensity applications High-intensity ultrasound has achieved a variety of important Perhaps the most ubiquitous is ultrasonic cleaning, in which ultrasonic vibrations are set up in small liquid tanks in which objects are placed for Cavitation of the liquid by the ultrasound, as well as the vibration, create turbulence in the liquid and result in the cleaning Ultrasonic cleaning is very popular for jewelry and has also been used with such items as dentures, surgical instruments, and small Degreasing is often enhanced by ultrasonic Large-scale ultrasonic cleaners have also been developed for use in assembly Ultrasonic machining employs the high-intensity vibrations of a transducer to move a machine If necessary, a slurry containing carborundum grit may be used; diamond tools can also be A variation of this technique is ultrasonic drilling, which makes use of pneumatic vibrations at ultrasonic frequencies in place of the standard rotary drill Holes of virtually any shape can be drilled in hard or brittle materials such as glass, germanium, or Ultrasonic soldering has become important, especially for soldering unusual or difficult materials and for very clean The ultrasonic vibrations perform the function of cleaning the surface, even removing the oxide layer on aluminum so that the material can be Because the surfaces can be made extremely clean and free from the normal thin oxide layer, soldering flux becomes Chemical and electrical uses The chemical effects of ultrasound arise from an electrical discharge that accompanies the cavitation This forms a basis for ultrasound's acting as a catalyst in certain chemical reactions, including oxidation, reduction, hydrolysis, polymerization and depolymerization, and molecular With ultrasound, some chemical processes can be carried out more rapidly, at lower temperatures, or more The ultrasonic delay line is a thin layer of piezoelectric material used to produce a short, precise delay in an electrical The electrical signal creates a mechanical vibration in the piezoelectric crystal that passes through the crystal and is converted back to an electrical A very precise time delay can be achieved by constructing a crystal with the proper These devices are employed in fast electronic timing Medical applications Although ultrasound competes with other forms of medical imaging, such as X-ray techniques and magnetic resonance imaging, it has certain desirable features—for example, Doppler motion study—that the other techniques cannot In addition, among the various modern techniques for the imaging of internal organs, ultrasonic devices are by far the least Ultrasound is also used for treating joint pains and for treating certain types of tumours for which it is desirable to produce localized A very effective use of ultrasound deriving from its nature as a mechanical vibration is the elimination of kidney and bladder Diagnosis Much medical diagnostic imaging is carried out with X Because of the high photon energies of the X ray, this type of radiation is highly ionizing—that is, X rays are readily capable of destroying molecular bonds in the body tissue through which they This destruction can lead to changes in the function of the tissue involved or, in extreme cases, its One of the important advantages of ultrasound is that it is a mechanical vibration and is therefore a nonionizing form of Thus, it is usable in many sensitive circumstances where X rays might be Also, the resolution of X rays is limited owing to their great penetrating ability and the slight differences between soft Ultrasound, on the other hand, gives good contrast between various types of soft Ultrasonic scanning in medical diagnosis uses the same principle as Pulses of high-frequency ultrasound, generally above one megahertz, are created by a piezoelectric transducer and directed into the As the ultrasound traverses various internal organs, it encounters changes in acoustic impedance, which cause The amount and time delay of the various reflections can be analyzed to obtain information regarding the internal In the B-scan mode, a linear array of transducers is used to scan a plane in the body, and the resultant data is displayed on a television screen as a two-dimensional The A-scan technique uses a single transducer to scan along a line in the body, and the echoes are plotted as a function of This technique is used for measuring the distances or sizes of internal The M-scan mode is used to record the motion of internal organs, as in the study of heart Greater resolution is obtained in ultrasonic imaging by using higher frequencies—, shorter A limitation of this property of waves is that higher frequencies tend to be much more strongly Because it is nonionizing, ultrasound has become one of the staples of obstetric During the process of drawing amniotic fluid in testing for birth defects, ultrasonic imaging is used to guide the needle and thus avoid damage to the fetus or surrounding Ultrasonic imaging of the fetus can be used to determine the date of conception, to identify multiple births, and to diagnose abnormalities in the development of the Ultrasonic Doppler techniques have become very important in diagnosing problems in blood In one technique, a three-megahertz ultrasonic beam is reflected off typical oncoming arterial blood with a Doppler shift of a few kilohertz—a frequency difference that can be heard directly by a Using this technique, it is possible to monitor the heartbeat of a fetus long before a stethoscope can pick up the Arterial diseases such as arteriosclerosis can also be diagnosed, and the healing of arteries can be monitored following A combination of B-scan imaging and Doppler imaging, known as duplex scanning, can identify arteries and immediately measure their blood flow; this has been extensively used to diagnose heart valve Using ultrasound with frequencies up to 2,000 megahertz, which has a wavelength of 75 micrometre in soft tissues (as compared with a wavelength of about 55 micrometre for light), ultrasonic microscopes have been developed that rival light microscopes in their The distinct advantage of ultrasonic microscopes lies in their ability to distinguish various parts of a cell by their Also, because they require no artificial contrast mediums, which kill the cells, acoustic microscopy can study actual living Therapy and surgery Because ultrasound is a mechanical vibration and can be well focused at high frequencies, it can be used to create internal heating of localized tissue without harmful effects on nearby This technique can be employed to relieve pains in joints, particularly in the back and Also, research is now being carried out in the treatment of certain types of cancer by local heating, since focusing intense ultrasonic waves can heat the area of a tumour while not significantly affecting surrounding Trackless surgery—that is, surgery that does not require an incision or track from the skin to the affected area—has been developed for several Focused ultrasound has been used for the treatment of Parkinson's disease by creating brain lesions in areas that are inaccessible to traditional A common application of this technique is the destruction of kidney stones with shock waves formed by bursts of focused In some cases, a device called an ultrasonic lithotripter focuses the ultrasound with the help of X-ray guidance, but a more common technique for destruction of kidney stones, known as endoscopic ultrasonic disintegration, uses a small metal rod inserted through the skin to deliver ultrasound in the 22- to 30-kilohertz frequency Infrasonics The term infrasonics refers to waves of a frequency below the range of human hearing—, below about 20 Such waves occur in nature in earthquakes, waterfalls, ocean waves, volcanoes, and a variety of atmospheric phenomena such as wind, thunder, and weather Calculating the motion of these waves and predicting the weather using these calculations, among other information, is one of the great challenges for modern high-speed TableAircraft, automobiles, or other rapidly moving objects, as well as air handlers and blowers in buildings, also produce substantial amounts of infrasonic Studies have shown that many people experience adverse reactions to large intensities of infrasonic frequencies, developing headaches, nausea, blurred vision, and On the other hand, a number of animals are sensitive to infrasonic frequencies, as indicated in the T It is believed by many zoologists that this sensitivity in animals such as elephants may be helpful in providing them with early warning of earthquakes and weather It has been suggested that the sensitivity of birds to infrasound aids their navigation and even affects their One of the most important examples of infrasonic waves in nature is in Three principal types of earthquake wave exist: the S-wave, a transverse body wave; the P-wave, a longitudinal body wave; and the L-wave, which propagates along the boundary of stratified L-waves, which are of great importance in earthquake engineering, propagate in a similar way to water waves, at low velocities that are dependent on S-waves are transverse body waves and thus can only be propagated within solid bodies such as P-waves are longitudinal waves similar to sound waves; they propagate at the speed of sound and have large When P-waves propagating from the epicentre of an earthquake reach the surface of the Earth, they are converted into L-waves, which may then damage surface The great range of P-waves makes them useful in identifying earthquakes from observation points a great distance from the In many cases, the most severe shock from an earthquake is preceded by smaller shocks, which provide advance warning of the greater shock to Underground nuclear explosions also produce P-waves, allowing them to be monitored from any point in the world if they are of sufficient The reflection of man-made seismic shocks has helped to identify possible locations of oil and natural-gas Distinctive rock formations in which these minerals are likely to be found can be identified by sonic ranging, primarily at infrasonic
首先要确定好核心期刊的定义,要清楚你说的是那种核心期刊。楼上回答比较偏面,单独说期刊名字也不够具体。医学类的核心期刊要分科技核心还是中文核心,或是CSCD。如果是科技核心,那么科学信息研究所每年都会更新一次(统计源)如果是中文核心,那么北京大学图书馆每3年更新一次(北大核心)根据不同的期刊,来去选择不同的目录,再确定有哪些期刊。
一般三类,五年一评。
像这类型的期刊类型是很多的,伱就说伱大概想写哪方面的内容那?
医学核心期刊是指经中国新闻出版总署审批准后公开发行的医学学术期刊。1、《中国社区医师》:国内发行量最大的国家级综合性医学期刊、中国知网收录期刊、旬刊。2、《医学信息》:国内发行速度最快的国家级综合性医学期刊、中国知网收录期刊、旬刊。3、《吉林医学》:创刊历史久远,综合性医学学术期刊、旬刊、中国知网收录期刊。4、《中国医药指南》:国家级科技期刊、半月刊、中国知网收录期刊。5、《中国中医药现代远程教育》:国家级科技期刊、半月刊、中国知网收录期刊。6、《内蒙古中医药》:综合性学术期刊、旬刊、万方收据库收录期刊,职称晋升认定期刊。7、《按摩与康复医学》:国家级优秀科技期刊、中华中医药学会系列、万方数据库收录、职称晋升认定期刊。8、《中国卫生产业》:国家级医药卫生期刊、月刊、中国核心期刊(遴选)数据库收录期刊。9、《中国当代医药》:国家级医药卫生专业刊物、旬刊、中国知网收录期刊。10、《中国美容医学》:中国科技核心期刊、月刊、中国知网收录期刊。11、《中国药业》:中国科技核心期刊、半月刊、中国知网收录期刊。12、《临床合理用药杂志》:综合性医药卫生类学术期刊、半月刊、中国知网收录期刊。
你的描述比较宽泛,投文章是要根据你做的具体的研究来的。建议你看一下这一领域里主流杂志发表的文章的参考文献,就基本能了解该领域大概有哪些杂志可供你选择。
首先,登录中国期刊全文数据库、万方数据库或者 维普数据库(此为中国三大专业文献数据库)或国外Pubmed/Medline等国外专业数据库,然后搜索相关的文献,写出您的文章。其次,再去以上数据库中搜索相关专业期刊编辑部信息(国家级或是非国家级,核心或者非核心,统计源或者非统计源期刊等等),找到投稿联系方式,这样的方法避免网上很多钓鱼网站,确保您投稿的期刊是合法的。最后,祝好运。欢迎交流。静石医疗,竭诚为您服务。
权威医学论文发表机构 数百种期刊资源 北大核心 科技核心 普通国家级省级期刊专业发表。我们承诺只做正规正刊,十多年 信誉发表。
权威医学论文发表机构 数百种期刊资源 北大核心 科技核心 普通国家级省级期刊专业发表。我们承诺只做正规正刊,十多年 信誉发表。
像这类型的期刊类型是很多的,伱就说伱大概想写哪方面的内容那?
1、中国医学影像技术 、中华超声影像学杂志 、中国医学影像学杂志、 中国临床医学影像杂志。2、《中国介入影像与治疗学》《中国医学影像技术》《中国医学影像学杂志》等中国知网都可以查到。
一般三类,五年一评。