ライフサイエンスコーパス: environmental science

1 organic compounds is a frequent question in environmental science.

2 lysis, electrochemistry, and atmospheric and environmental science.

3 needed in many areas of geobiochemistry and environmental science.

4 s for better integration of macroecology and environmental science.

5 f fundamental importance in many branches of environmental science.

6 s ranging from medicine and biotechnology to environmental science.

7 h fundamental catalytic research and applied environmental science.

8 t between archaeology and the biological and environmental sciences.

9 numerous fields ranging from biochemistry to environmental sciences.

10 to assess geochemical processes in Earth and environmental sciences.

11 nd, which is a standard sample often used in environmental sciences.

12 ain pivotal for both fundamental and applied environmental sciences.

13 vides a powerful methodology in the field of environmental sciences.

14 reat benefit to medical, pharmaceutical, and environmental sciences.

15 dicine, biotechnology, chemical sciences and environmental sciences.

16 alignment in purpose between nutritional and environmental sciences.

17 ometers and tracers in earth, planetary, and environmental sciences.

18 (PTR-MS) has become a reference technique in environmental science allowing for VOC monitoring with l

19 will prove useful for the study of ozone in environmental science and biology, and so possibly provi

20 ulum itself is built on three primary cores: environmental science and engineering, business and mana

21 stallinity, this work is equally relevant to environmental science and environmental technology becau

22 Despite their fundamental importance in environmental science and policy, there has been no syst

23 al analytical information for biological and environmental sciences and industrial waste management.

24 damental challenge in industrial processing, environmental sciences and medical applications.

25 or a number of fields including biomedicine, environmental science, and biosecurity.

26 +) is a very important metal ion in biology, environmental science, and industry.

27 great promise in the fields of biomedicine, environmental science, and natural resources.

28 uence applications in agriculture, medicine, environmental science, and synthetic biology.

29 molecules across medical, biotechnology, and environmental science applications.

30 nd other fields including physics, earth and environmental sciences, archaeology, biomedicine, and ma

31 nalyses in chemistry, materials science, and environmental science are currently performed using tech

32 has important applications in areas such as environmental science, biomedical research and medical d

33 owth curves has importance in food sciences, environmental sciences, bioremediation and in understand

34 rucial importance to Earth's climate and the environmental sciences, but it is not understood at the

35 analyses and not fully characterized by the environmental science community, which may enter the env

36 y (i.e., in both generation and storage) and environmental science (e.g., purification/remediation).

37 n processing, catalysis, biomedical science, environmental science, energy conversion and storage, ad

38 nic pollutants is a formidable challenge for environmental sciences, engineering, and regulation.

39 r of exciting application areas in earth and environmental sciences, for example, natural abundance d

40 ological research, medicine, agriculture and environmental science, has led to unprecedented growth i

41 ral examples for the application of APXPS to environmental science, heterogeneous catalysis, and elec

42 ques in the field of nano(eco)toxicology and environmental sciences, including atomic force microscop

43 This report derives from a Health and Environmental Sciences Institute (HESI) workshop held in

44 sembled by a working group of the Health and Environmental Sciences Institute's Technical Committee o

45 umber of metagenomic studies in medicine and environmental sciences is creating increasing demands on

46 Data availability in environmental sciences is growing rapidly.

47 icine, tissue engineering, renewable energy, environmental science, nanotechnology and material scien

48 om materials science, biomaterials, geology, environmental science, palaeontology and cultural herita

49 and challenges in global change research and environmental science raise the need for replicated expe

50 guided by three emergent hypotheses in human-environmental sciences regarding the relationships among

51 al exposure science represents a frontier of environmental science that is emerging and quickly evolv

52 effect of freeze-thaw cycles is important in environmental science, the built environment and cultura

53 es, particularly in medical, veterinary, and environmental sciences, this enabling technology has had

54 experts from population, developmental, and environmental science to encourage debate and collaborat

55 ls structure and dynamics, to geophysics and environmental science, to biophysics and protein crystal