ライフサイエンスコーパス: astronomy

1 ics and other data-science subdomains (e.g., astronomy).

2 tions, ultra-fast science, and observational astronomy.

3 w light pollution and behavioral interest in astronomy.

4 onal waves led to a focus on multi-messenger astronomy.

5 ranging from biology to materials science to astronomy.

6 alysis to biomedical diagnostics, vision and astronomy.

7 as molecular biology, particle physics, and astronomy.

8 of the universe is a long-standing quest in astronomy.

9 om communications to radar, broadcasting and astronomy.

10 ay have substantial effects in observational astronomy.

11 in the interstellar medium with far-infrared astronomy.

12 s, has brought about a revolution in optical astronomy.

13 the Kuiper belt-has opened a new frontier in astronomy.

14 entific fields ranging from X-ray imaging to astronomy.

15 a promising route for future multi-messenger astronomy.

16 ling components were drawn from the field of astronomy.

17 currently one of the most exciting areas of astronomy.

18 mistry, biology, materials science, and even astronomy.

19 bled breakthrough observations from radar to astronomy.

20 cation in astronomical environments by radio astronomy.

21 ond a few niche domains, such as defense and astronomy.

22 pose significant challenges to ground-based astronomy(1).

23 ty(1,2), medicine(3), crystallography(4) and astronomy(5).

24 tions(6), lidar(7), optical computing(8) and astronomy(9).

25 be useful, except in large-scale problems in astronomy and astrodynamics.

26 Particle physics, astronomy and climate science, for example, have all gre

27 Suddenly, it seemed, astronomy and commercial space activity were in conflict

28 ry and accomplishments of gravitational-wave astronomy and look towards the future.

29 ise floor in potential applications in radio astronomy and nuclear magnetic imaging.

30 e abundance ratios have an important role in astronomy and planetary sciences, providing insights int

31 enormous impact on the public's view of both astronomy and theology.

32 ir values was discussed in particle physics, astronomy, and cosmology.

33 ser-induced guide star has long been used in astronomy, and more recently in microscopy to compensate

34 it went on to change forever many fields of astronomy, and to capture the public's imagination with

35 erizing rocky exoplanets is a central aim of astronomy, and yet the search for atmospheres on rocky e

36 the potential of the method in a challenging astronomy application.

37 Large scientific projects in genomics and astronomy are influential not because they answer any si

38 They also open the window to particle astronomy, as the magnetic fields along their paths are

39 nguage AI assistant tailored for research in astronomy, astrophysics, cosmology, and astronomical ins

40 , thus represent important targets for radio astronomy because they offer the possibilities of confir

41 a crucial role in the development of stellar astronomy because, as a consequence of the stars having

42 Neutrino astronomy beyond the Sun was first imagined in the late

43 Although the effects of light pollution on astronomy, biology, ecology, and health are well-known,

44 ide variety of applications (particularly in astronomy), but are difficult to integrate into large ar

45 Until the Hubble, breakthroughs in astronomy came from big telescopes on mountain-top obser

46 pproaches, commonly used in epidemiology and astronomy, can be applied in the context of genetic sequ

47 asked 4,147 scientists from six disciplines (astronomy, cardiology, materials science, political scie

48 Shock and anger are palpable in the astronomy community.

49 of cosmic structure; summarize its impact on astronomy, cosmology, and physics; and look ahead by out

50 of active learning in five core physics and astronomy courses comprising 2,145 students from the Mid

51 c disciplines, such as planetary science and astronomy, each of which are grappling with and developi

52 py, light microscopy, medical X-ray imaging, astronomy, etc.

53 sociated primarily with particle physics and astronomy experiments.

54 Radiometers are crucial instruments in radio astronomy, forming the primary component of nearly all r

55 demonstrated with datasets from proteomics, astronomy, genomics, remote sensing, census analysis, an

56 in fields as diverse as physics, chemistry, astronomy, geoscience, biology, psychology, materials sc

57 Astronomy has benefited from improvements in technology

58 Since then, gravitational-wave astronomy has enabled tests of the nature of gravity and

59 nning in the early 1960s, the field of X-ray astronomy has exploded, experiencing a ten-billion-fold

60 Globular clusters and x-ray astronomy have a long and fruitful history.

61 s of artificial light at night on scientific astronomy, human health, ecological processes and aesthe

62 Our adaptation of radio astronomy imaging techniques to study extremely transien

63 One of the major goals for astronomy in the next decades is the remote search for b

64 arriers of the diffuse interstellar bands in astronomy, indicating their persistence in interstellar

65 sis, we used location information to examine astronomy interest data for millions of US residents.

66 Astronomy is at times a science of unexpected discovery.

67 One aim of modern astronomy is to detect temperate, Earth-like exoplanets

68 OFIA (Stratospheric Observatory for Infrared Astronomy) legacy program FEEDBACK of the massive star-f

69 n of genius-combining cycles from Babylonian astronomy, mathematics from Plato's Academy and ancient

70 is a ubiquitous challenge, crucial in radio astronomy, medical imaging, navigation, and classical an

71 effect has well-established applications in astronomy, medicine, radar and metrology.

72 tion by stimulated emission of radiation; in astronomy mega-masers are masers in galaxies that are >/

73 d applied sciences, including geochronology, astronomy, metabolism, etc., rely on the ability of mass

74 V for single 6-keV photons, and future X-ray astronomy missions anticipate the need for 1,000-pixel a

75 ose to the targets required for future X-ray astronomy missions.

76 e critical for applications in spectroscopy, astronomy, navigation or telecommunications.

77 For example, in astronomy, NumPy was an important part of the software s

78 ope, an instrument primarily build for radio-astronomy observations.

79 h a capability that links the National Radio Astronomy Observatory's Very Large Array radio interfero

80 e been used widely to correct aberrations in astronomy, offer a solution here but also present new ch

81 Exoplanet detections have revolutionized astronomy, offering new insights into solar system archi

82 that span completely different fields, from astronomy or meteorology to spectroscopy and optical cir

83 Major advances in observational astronomy over the past 20 years have revolutionized our

84 was thought until recently to be useless to astronomy, primarily because the opacity of the interste

85 The assumption is valid for many modern astronomy projects, with the issue of big data storage o

86 Trained on the complete collection of astronomy-related arXiv papers from 2007 to 2024 along w

87 teorite samples is among the most ancient of astronomy-related questions, which at larger scales has

88 biological sensing, standoff detection, and astronomy rely on devices that operate in the mid-infrar

89 ation, and the integrity of the ground-based astronomy research enterprise.

90 e groundbreaking observatories lead an X-ray astronomy revolution: revealing the physical processes a

91 Over the past six decades, astronomy, space science, and the space industry have se

92 itive phenomena is of critical importance in astronomy, spectroscopy, biology, and remote sensing.

93 st impactful findings ever in the history of astronomy--the identification of life beyond Earth.

94 ion observations are often possible in radio astronomy, they are usually limited to quite narrow fiel

95 and so deeply embedded into the language of astronomy through the Hubble diagram, the Hubble constan

96 highly sensitive measurement techniques from astronomy to bioimaging.

97 ensing modality with broad applications from astronomy to biology.

98 From astronomy to cell biology, the manner in which light pro

99 dditional perspectives in areas ranging from astronomy to medicine.

100 O) has revolutionized imaging in fields from astronomy to microscopy by correcting optical aberration

101 l role in a wide range of fields, from radio astronomy to nuclear magnetic resonance imaging.

102 t as well as the chop-nod method in infrared astronomy, to characterize nanomaterials without the inf

103 ication of AO for high-resolution imaging in astronomy, vision science and microscopy.

104 A surprising discovery in x-ray astronomy was that clusters of galaxies often contain va

105 d to the development of people's interest in astronomy, which often serves as a "gateway" to science

106 ng optical devices, originally developed for astronomy, whose optical properties can be changed in re

107 th three other major generators of Big Data: astronomy, YouTube, and Twitter.