ライフサイエンスコーパス: radiation source

1 (192)Ir (15 Gy delivered 2 mm away from the radiation source).

2 matrix environment and a tunable narrowband radiation source.

3 se of active interrogation using an external radiation source.

4 onary artery segments by using a synchrotron radiation source.

5 exposed to 10 Gy WBI using Cesium-137 as the radiation source.

6 ies with the help of a tunable synchrotron X-radiation source.

7 ary intervention but were not covered by the radiation source.

8 ter-based intervention and the length of the radiation source.

9 ation of the haversian canals as a potential radiation source.

10 radiation, and at same dose rates using same radiation source.

11 ature diffraction images irrespective of the radiation source.

12 roperties of the crystals rather than to the radiation source.

13 esearch Institute high level cobalt-60 gamma-radiation source.

14 ate for a miniaturized solid-state cyclotron radiation source.

15 sented in the manuscript using four pairs of radiation sources.

16 ving organisms that are regularly exposed to radiation sources.

17 m and is therefore well suited for broadband radiation sources.

18 he development of tunable and multifrequency radiation sources.

19 ned from the same volunteers and ultraviolet radiation sources.

20 is a feature hard to mimic with conventional radiation sources.

21 duced neutron flux of both moving and static radiation sources.

22 act and industrially robust accelerators and radiations sources.

23 ent doses (10, 20, and 50 Gy) from different radiation sources (60)Co or (137)Cs).

24 At a synchrotron radiation source, a crystal with a tetragonal space grou

25 the first step demonstration towards GW THz radiation source and GV/m THz wakefield accelerator.

26 entional echocardiographer to stand near the radiation source and patient, the primary source of scat

27 latter models were determined using in-house radiation source and the X-ray dose received by Pdx crys

28 red vessel is irradiated, using a variety of radiation sources and delivery systems.

29 Advances in synchrotron radiation sources and detector technology are pushing th

30 l light-matter interactions to make brighter radiation sources and unleash unprecedented control over

31 ing the X-ray optical problem at synchrotron radiation sources and X-ray free-electron lasers.

32 ures of merit indicate that the data of both radiation sources are of equivalent quality.

33 energies, suggesting that laser plasma based radiation sources are promising for advanced application

34 lopment of compact laser-driven particle and radiation sources, as well as investigations of some lab

35 Here we propose a tunable polarized radiation source based on a helical plasma undulator in

36 of an efficient, megawatt coherent Cherenkov radiation source based on a two-dimensional periodic sur

37 n the ID14B BioCARS (Consortium for Advanced Radiation Sources) beamline at the Advanced Photon Sourc

38 ial as the basis for next generation compact radiation sources because of their extremely high accele

39 or dipole magnet beamline at the synchrotron radiation source BESSY II is about 4.3 nm.

40 facilities worldwide as complementary space radiation sources can help alleviate the shortage of ava

41 sing the latest third-generation synchrotron radiation sources, can be inverted to obtain full three-

42 ich take advantage of the latest synchrotron radiation sources, can be used to obtain quantitative th

43 A solid-state implementation of a cyclotron radiation source consisting of arrays of semicircular ge

44 Inadequate radiation source coverage of the injured segment (GM) ha

45 of three exposures on alternating days to a radiation source covering a cumulative UVR exposure rang

46 he ever-increasing brightness of synchrotron radiation sources demands improved X-ray optics to utili

47 LPP) for extreme ultraviolet (EUV) and X-ray radiation sources due to the expected plasma conditions

48 The impact of all relevant radiation sources during different stages of the operati

49 The high brilliance of modern synchrotron radiation sources facilitates experiments with high-ener

50 Sadly, conventional radiation sources (gamma or X rays, electrons) used for

51 raction studies carried out at a synchrotron radiation source have allowed the structure solution and

52 , the doors of the world's first synchrotron radiation source have closed.

53 evices; sensors; field emission displays and radiation sources; hydrogen storage media; and nanometer

54 t with simulated free-moving single detector radiation source imaging scenarios.

55 rapeutic NM procedures without shielding the radiation source in the 1980s (HR, 1.32; 95% CI: 1.04, 1

56 arrangement is a novel optical recombination radiation source in which the electrons and holes are in

57 each conducted respective assessments of all radiation sources in the United States and worldwide.

58 use in vacuum experimental chambers of X-ray radiation sources including the newly developed, first-o

59 s show reasonable response under a series of radiation sources, including (241)Am and (57)Co radiatio

60 ions in free electron lasers and synchrotron radiation source injectors.

61 is a well-established method at synchrotron radiation sources, its near-field analog has received le

62 r constitutes a millimetre-sized synchrotron radiation source of X-rays.

63 Next-generation synchrotron radiation sources, such as X-ray free-electron lasers, e

64 resolved experiments can be conducted at the radiation source that best matches the desired time reso

65 y unexposed buttock skin with an ultraviolet radiation source that complied with European recommendat

66 In outer space, protons are the primary radiation source that poses a range of potential health

67 rt an injectable nanoparticle-based internal radiation source that potentially offers more efficaciou

68 Furthermore, for ionizing radiation sources that cannot be imaged using these stan

69 ized to predict a new path towards nonlinear radiation sources that combine resonant upconversion wit

70 Importantly, in addition to the synchrotron radiation source, this approach has been demonstrated fo

71 d at the output facet of any electromagnetic radiation source to deflect electromagnetic waves at a d

72 l, compared with the cell size, and when the radiation sources were on the cell surface.

73 Two electromagnetic radiation sources were used to irradiate the lower back

74 lecular crystals at the CXLS and synchrotron radiation sources, which holds enormous potential for ad

75 iheterodyne techniques using frequency combs-radiation sources whose lines are perfectly evenly-space

76 We demonstrate that a radiation source with millimeter size and peak brillianc

77 f a tungsten lamp as an inexpensive infrared radiation source, with cooling effected with a solenoid-

78 option allows simultaneously two independent radiation sources, with a full coverage of the EUV (2.5