Books: 'Low temperature storage assay'

1

Hudson, Glyn. Micropropagation and low temperature storage of Dieffenbachia. London: North East London Polytechnic, 1985.

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2

Hudson, Glyn. Micropropagation and low temperature storage of dieffenbachia. London: NELP, 1986.

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3

Scurlock, R. G. Low-loss storage and handling of cryogenic liquids: The application of cryogenic fluid dynamics. Southampton: Kryos Publications, 2006.

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4

Moran, Matthew E. Liquid Transfer Cryogenic Test Facility: Initial hydrogen and nitrogen no-vent fill data. [Washington, D.C.]: NASA, 1990.

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5

International Symposium on Refrigeration, Energy and Environment (1992 Trondheim, Norway). Proceedings from the International Symposium on Refrigeration, Energy and Environment: Trondheim, Norway, June 22-24, 1992. Trondheim: NTH-SINTEF, 1992.

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6

Rivers, H. Kevin. Cyclic cryogenic thermal-mechanical testing of an X-33/RLV liquid oxygen tank concept. Hampton, Va: National Aeronautics and Space Administration, Langley Research Center, 1999.

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7

T, Van Dresar Neil, Hasan Mohammad M, and United States. National Aeronautics and Space Administration., eds. A pressure control analysis of cryogenic storage systems. [Washington, DC]: National Aeronautics and Space Administration, 1991.

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8

D, Scarlotti R., and United States. National Aeronautics and Space Administration. Scientific and Technical Information Office., eds. Space station experiment definition: Long-term cryogenic fluid storage. [Washington, DC]: National Aeronautics and Space Administration, Scientific and Technical Information Office, 1987.

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9

Leary, Lewis W. Damping degradation in incramute and sonoston due to low temperature storage. 1986.

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10

Matthias, Gottmann, and United States. National Aeronautics and Space Administration., eds. Thermal control systems for low-temperature heat rejection on a lunar base: Semiannual status report for grant NAG5-1572. Tucson, AZ: Dept. of Aerospace and Mechanical Engineering, University of Arizona, 1992.

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11

Matthias, Gottmann, Nanjundan Ashok, and Goddard Space Flight Center, eds. Thermal control systems for low-temperature heat rejection on a lunar base: Annual progress report for grant NAG5-1572 (MOD). [Tucson, Ariz.?]: Aerospace and Mechanical Engineering, University of Arizona, 1993.

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12

Matthias, Gottmann, Nanjundan Ashok, and Goddard Space Flight Center, eds. Thermal control systems for low-temperature heat rejection on a lunar base: Annual progress report for grant NAG5-1572 (MOD). [Tucson, Ariz.?]: Aerospace and Mechanical Engineering, University of Arizona, 1993.

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13

Center, Langley Research, ed. Cyclic cryogenic thermal-mechanical testing of an X-33/RLV liquid oxygen tank concept. Hampton, Va: National Aeronautics and Space Administration, Langley Research Center, 1999.

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14

Cyclic cryogenic thermal-mechanical testing of an X-33/RLV liquid oxygen tank concept. Hampton, Va: National Aeronautics and Space Administration, Langley Research Center, 1999.

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15

Center, Langley Research, ed. Cyclic cryogenic thermal-mechanical testing of an X-33/RLV liquid oxygen tank concept. Hampton, Va: National Aeronautics and Space Administration, Langley Research Center, 1999.

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16

Center, Langley Research, ed. Cyclic cryogenic thermal-mechanical testing of an X-33/RLV liquid oxygen tank concept. Hampton, Va: National Aeronautics and Space Administration, Langley Research Center, 1999.

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17

Fuss, Sabine. The 1.5°C Target, Political Implications, and the Role of BECCS. Oxford University Press, 2017. http://dx.doi.org/10.1093/acrefore/9780190228620.013.585.

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Abstract:

The 2°C target for global warming had been under severe scrutiny in the run-up to the climate negotiations in Paris in 2015 (COP21). Clearly, with a remaining carbon budget of 470–1,020 GtCO2eq from 2015 onwards for a 66% probability of stabilizing at concentration levels consistent with remaining below 2°C warming at the end of the 21st century and yearly emissions of about 40 GtCO2 per year, not much room is left for further postponing action. Many of the low stabilization pathways actually resort to the extraction of CO2 from the atmosphere (known as negative emissions or Carbon Dioxide Removal [CDR]), mostly by means of Bioenergy with Carbon Capture and Storage (BECCS): if the biomass feedstock is produced sustainably, the emissions would be low or even carbon-neutral, as the additional planting of biomass would sequester about as much CO2 as is generated during energy generation. If additionally carbon capture and storage is applied, then the emissions balance would be negative. Large BECCS deployment thus facilitates reaching the 2°C target, also allowing for some flexibility in other sectors that are difficult to decarbonize rapidly, such as the agricultural sector. However, the large reliance on BECCS has raised uneasiness among policymakers, the public, and even scientists, with risks to sustainability being voiced as the prime concern. For example, the large-scale deployment of BECCS would require vast areas of land to be set aside for the cultivation of biomass, which is feared to conflict with conservation of ecosystem services and with ensuring food security in the face of a still growing population.While the progress that has been made in Paris leading to an agreement on stabilizing “well below 2°C above pre-industrial levels” and “pursuing efforts to limit the temperature increase to 1.5°C” was mainly motivated by the extent of the impacts, which are perceived to be unacceptably high for some regions already at lower temperature increases, it has to be taken with a grain of salt: moving to 1.5°C will further shrink the time frame to act and BECCS will play an even bigger role. In fact, aiming at 1.5°C will substantially reduce the remaining carbon budget previously indicated for reaching 2°C. Recent research on the biophysical limits to BECCS and also other negative emissions options such as Direct Air Capture indicates that they all run into their respective bottlenecks—BECCS with respect to land requirements, but on the upside producing bioenergy as a side product, while Direct Air Capture does not need much land, but is more energy-intensive. In order to provide for the negative emissions needed for achieving the 1.5°C target in a sustainable way, a portfolio of negative emissions options needs to minimize unwanted effects on non–climate policy goals.

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18

Rai, Dibya Prakash, ed. Advanced Materials and Nano Systems: Theory and Experiment - Part 2. BENTHAM SCIENCE PUBLISHERS, 2022. http://dx.doi.org/10.2174/97898150499611220201.

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The discovery of new materials and the manipulation of their exotic properties for device fabrication is crucial for advancing technology. Nanoscience, and the creation of nanomaterials have taken materials science and electronics to new heights for the benefit of mankind. Advanced Materials and Nanosystems: Theory and Experiment covers several topics of nanoscience research. The compiled chapters aim to update students, teachers, and scientists by highlighting modern developments in materials science theory and experiments. The significant role of new materials in future technology is also demonstrated. The book serves as a reference for curriculum development in technical institutions and research programs in the field of physics, chemistry and applied areas of science like materials science, chemical engineering and electronics. This part covers 12 topics in these areas: 1. Recent advancements in nanotechnology: a human health Perspective 2. An exploratory study on characteristics of SWIRL of AlGaAs/GaAs in advanced bio based nanotechnological systems 3. Electronic structure of the half-Heusler ScAuSn, LuAuSn and their superlattice 4. Recent trends in nanosystems 5. Improvement of performance of single and multicrystalline silicon solar cell using low-temperature surface passivation layer and antireflection coating 6. Advanced materials and nanosystems 7. Effect of nanostructure-materials on optical properties of some rare earth ions doped in silica matrix 8. Nd2Fe14B and SmCO5: a permanent magnet for magnetic data storage and data transfer technology 9. Visible light induced photocatalytic activity of MWCNTS decorated sulfide based nano photocatalysts 10. Organic solar cells 11. Neodymium doped lithium borosilicate glasses 12. Comprehensive quantum mechanical study of structural features, reactivity, molecular properties and wave function-based characteristics of capmatinib

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Books on the topic 'Low temperature storage assay'

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