ライフサイエンスコーパス: radioactive waste

1 el to recover fissile materials and mitigate radioactive waste.

2 is the long-term safety of repositories for radioactive waste.

3 cement-based near field of a repository for radioactive waste.

4 estigated in the context of safe disposal of radioactive waste.

5 5 fission and comprises a large component of radioactive waste.

6 of an RIA without the associated problems of radioactive waste.

7 hat results in large quantities of hazardous radioactive waste.

8 ithout the generation of large quantities of radioactive waste.

9 in a global legacy of contaminated land and radioactive waste.

10 e safety case for the underground storage of radioactive waste.

11 ing off-gas is essential to the treatment of radioactive waste.

12 s formed including in geological disposal of radioactive wastes.

13 r fuel rods or contamination with high-level radioactive wastes.

14 rock for retrievable disposal of high-level radioactive wastes.

15 erm radiotoxicity of nuclear fuels and other radioactive wastes.

16 of release from deep geological disposal of radioactive waste and incorporation into the biosphere.

17 in view of the treatment of the accumulated radioactive waste and of the recycling of minor actinide

18 ments relevant to the geological disposal of radioactive waste and radionuclide contaminated land.

19 s is inherently coupled to issues concerning radioactive waste and safety precautions.

20 t component of this legacy and is present in radioactive wastes and at many contaminated sites.

21 ee Mile Island nuclear power plant and other radioactive wastes), and, as specially tailored desiccan

22 nyl-(13/14)C] alkyl amides, thereby reducing radioactive waste, and handling of radioactive materials

23 inates the need for enriched uranium and the radioactive waste associated with the processing of uran

24 hould not be a limiting factor in processing radioactive wastes, assuming Tc as Tc(7+) and similariti

25 gineer D. radiodurans for treatment of mixed radioactive wastes by developing a strain to detoxify bo

26 s) in future deep geological repositories of radioactive waste can influence the migration behavior o

27 indings exemplify the need to develop robust radioactive waste characterization procedures in support

28 Radioactive waste containing a few grams of plutonium (P

29 During the 1960s, radioactive waste containing small amounts of plutonium

30 sistant bacterium for the treatment of mixed radioactive wastes containing ionic mercury.

31 many processes on a global scale, including radioactive waste containment, desalination, and enhance

32 bility in sulfidic environments pertinent to radioactive waste disposal and contaminated land scenari

33 anium is a risk-driving radionuclide in both radioactive waste disposal and contaminated land scenari

34 ies were measured in sediments from a former radioactive waste disposal basin located on the Savannah

35 background sediments (22-44 Bq/kg) and above radioactive waste disposal threshold regulations, posing

36 The increased costs of radioactive waste disposal together with heightened secu

37 urbation of magnetite in systems relevant to radioactive waste disposal.

38 a formation selected in France for possible radioactive waste disposal.

39 igher throughput and eliminated the need for radioactive waste disposal.

40 odeling Tc fate at contaminated sites and in radioactive waste disposal.

41 of post-closure safety models for U-bearing radioactive waste disposal.

42 higher throughput and eliminate the need for radioactive waste disposal; hence, they are appropriate

43 Beginning in the 1940s, radioactive waste from the effort to develop an atomic b

44 roundwater have been contaminated by leaking radioactive waste generated in the United States during

45 erred long-term solution for higher activity radioactive wastes (HAW) including intermediate level wa

46 r the deep geological disposal of high-level radioactive waste (HLW), bentonite is proposed as a pote

47 Portland cement-based grouts used for radioactive waste immobilisation contain a Ca- and Si-ri

48 le environments, such as nuclear reactors or radioactive waste immobilization, require extremely high

49 a neutron poison and as a seed for producing radioactive waste in nuclear systems has driven a renewe

50 ogical basis of microbial transformations of radioactive waste in these settings.

51 red concept for disposing of higher activity radioactive wastes including ILW is via deep geological

52 will be present in significant quantities in radioactive wastes including intermediate-level waste (I

53 the proposed repository site for high-level radioactive waste indicate that the crust extended by 0.

54 The significant abundance of uranium in radioactive waste inventories worldwide necessitates a t

55 dramatically reduces the synthetic steps and radioactive waste involved in preparation of (14)C label

56 Processing and managing radioactive waste is a great challenge worldwide as it i

57 High-level radioactive waste is accumulating at temporary storage l

58 Geological disposal of radioactive waste is being planned by many countries.

59 as been made in reducing the volume of final radioactive waste, its management remains one of the mos

60 Tc immobilization is crucial for radioactive waste management and environmental remediati

61 However, due to several limitations such as radioactive waste management and lower sensitivity, a ne

62 de analogues and TK enzymes while decreasing radioactive waste, minimizing assay time, increasing acc

63 Over 100 million gallons of liquid radioactive waste of unknown composition will be chemica

64 ssay is the more than 3000-fold reduction in radioactive waste over existing protocols.

65 This has implications for radioactive waste processing because Tc-99, the second r

66 in Spent Nuclear Fuel (SNF) reprocessing and radioactive waste processing.

67 rent projects for the disposal of high-level radioactive waste rely on underground burial and confine

68 geological repositories for the disposal of radioactive waste rely partly on the integrity of canist

69 disposal of cementitious intermediate level radioactive waste, remains unexplored.

70 h relevance for the near-field of high-level radioactive waste repositories, was investigated under a

71 nt to the formation of mineralized deposits, radioactive waste repositories, wetlands, and other U- a

72 f relevance in the thermodynamic modeling of radioactive waste repositories, where the predominance o

73 ficient retention of Np in the near-field of radioactive waste repositories.

74 lates and Ca(II) are typical in cementitious radioactive waste repositories.

75 nment as it might occur in the vicinity of a radioactive waste repository or a reprocessing plant.

76 efore be considered during the evaluation of radioactive waste repository sites and the risk assessme

77 Water samples from a legacy radioactive waste site (Little Forest, Australia) were s

78 replica trench located adjacent to a legacy radioactive waste site are presented in this study.

79 The high cost of remediating radioactive waste sites from nuclear weapons production

80 at concentrations well above those found in radioactive waste sites, and to effectively reduce Hg (I

81 ation can be provided for the remediation of radioactive waste sites.

82 roethylene at levels exceeding those of many radioactive waste sites.

83 maintained over the hazardous life cycle of radioactive wastes (some ~10,000 years).

84 within a few kilometers of both the CNPP and radioactive waste storage facilities.

85 ial applications, including luminescence and radioactive waste storage forms.

86 lications ranging from solid electrolytes to radioactive waste storage.

87 tability of deep geological repositories for radioactive waste storage.

88 termination of the radionuclide inventory in radioactive waste streams, including those generated dur

89 ng strict guidelines for safely disposing of radioactive waste such as urine collected in lead-lined

90 eous electrolytes characteristic to mine and radioactive waste tailings as well as the formation of c

91 A novel nanotechnology for the separation of radioactive waste that uses magnetic nanoparticles (MNPs

92 ssing aspects such as the utility of burying radioactive waste, the remediation of mixtures of organi

93 As the dominant radionuclide by mass in many radioactive wastes, the control of uranium mobility in c

94 nthetic costs and limiting the generation of radioactive waste, this procedure will facilitate the ac

95 nthetic costs and limiting the generation of radioactive waste, this procedure will facilitate the la

96 During the processing of low-activity radioactive waste to generate solid waste forms (e.g., g

97 lerance of potential hosts for actinides and radioactive wastes to be tailored.

98 ocesses involving corrosive effluents (e.g., radioactive waste), was also assessed.

99 tories, specifically the migration of leaked radioactive waste, will benefit from having ultrafast AI

100 tivities have resulted in a global legacy of radioactive wastes, with uranium considered a key radion