「deuterium」の共起表現一覧(2語右で並び替え)
該当件数 : 63件
| The reactor uses heavy water ( | deuterium) as a moderator and coolant. |
| ause a brief fusion reaction by accelerating | deuterium into a tritium target (or potentially vice v |
| n specialist, raised the question of whether | deuterium could affect hydrogen bonds between the odor |
| adiation would be lost during the process of | deuterium burning and, in 1982, the final design of th |
| A planned upgrade to heavy water ( | deuterium oxide) as central cooling water will improve |
| In Vienna Standard Mean Ocean Water, | deuterium occurs at a rate of 155.76 ppm. |
| n: a deuterated compound will show a peak in | deuterium NMR but not proton NMR. |
| The nucleus of | deuterium is called a deuteron. |
| sion of matter to helium-4 and less unburned | deuterium that can remain. |
| and started to bombard the uranium-239 with | deuterium to create the element 94. |
| Replacement of hydrogen by | deuterium in DKDP lowers the frequency of O-H vibratio |
| Deuterium NMR has a range of chemical shift similar to | |
| compounds), including significant amounts of | deuterium and helium-3. |
| h the hydrogen atoms ("H") are replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| ich the hydrogen atom ("H") is replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| h the hydrogen atom ("H") is replaced with a | deuterium (heavy hydrogen) isotope ("D"). |
| ich the hydrogen atom ("H") is replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| ich the hydrogen atom ("H") is replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| ich the hydrogen atom ("H") is replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| ich the hydrogen atom ("H") is replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| ich the hydrogen atom ("H") is replaced with | deuterium (heavy hydrogen) isotope ("D"). |
| gen atom has been isotopically labeled using | deuterium (shown in red). |
| mass limit above which an object can undergo | deuterium fusion in its core, which some take to be th |
| Deuterium NMR is NMR spectroscopy of deuterium (2D), a | |
| ozzle, the mixture of helium and hydrogen or | deuterium gas is injected to the exhaust stream; the h |
| It used | deuterium, an isotope of hydrogen, as a neutron modera |
| goals of FUSE was to study the abundance of | deuterium, an isotope of hydrogen. |
| ron ring room and the former Continuous Wave | Deuterium Demonstrator laboratory. |
| olved if there were some means of generating | deuterium, but large efforts in the 1970s failed to co |
| This makes the | deuterium fluoride laser usable for terrestrial operat |
| The | deuterium fluoride laser constructionally resembles a |
| It is a | deuterium fluoride laser, a type of chemical laser. |
| ndary, UScoCTIO 108B, with a mass around the | deuterium burning limit of 13 Jupiter masses, would be |
| is star, including one with a mass above the | deuterium fusion limit that is often used as the divid |
| anian study found that water with only 30ppm | deuterium produced marked improvement in survival rate |
| rotons and therefore they can be replaced by | deuterium with N-deuteriocyclohexylamide. Photolysis o |
| er (DDW) is water which has been depleted of | deuterium, a naturally-occurring isotope of hydrogen. |
| Hence the fact that | deuterium is not an extremely rare component of the un |
| This inconsistency between observations of | deuterium and observations of the expansion rate of th |
| different smells (metallocene experiment and | deuterium replacement of molecular hydrogen). |
| aving the symbol 2H+ or D+, is the +1 ion of | deuterium, 2H or D. |
| production of heavy water involves isolating | deuterium and produces light water as a by-product. |
| ZED-2 - Zero Energy | Deuterium 200W Reactor (1960-). |
| In addition, | deuterium is readily available in sea water, unlike tr |
| The exchange of hydrogen with | deuterium in some of the molecules creates scattering |
| an normal proportion of the hydrogen isotope | deuterium in some manner, however D2O (heavy water) is |
| Deuterium NMR spectra are especially informative in th | |
| rd explanation now used for the abundance of | deuterium is that the universe does not consist mostly |
| sists of baryons, then there is far too much | deuterium in the universe. |
| The "secondary" fusion stage used liquid | deuterium despite the difficulty of handling this mate |
| d C. Urey, in his work with hydrogen isotope | deuterium demonstrated the existence of heavy water, t |
| above, fail to account for the abundance of | deuterium in the cosmos, because deuterium easily unde |
| ncreasing the density and temperature of the | deuterium to the level needed to sustain a thermonucle |
| One example is the use of | deuterium NMR to study lipid membrane phase behavior. |
| tural uranium fuel moderated by heavy water ( | deuterium oxide) to control neutron flux. |
| n those required for the classical hydrogen, | deuterium and tritium fusion previously considered. |
| boosting with fusion, using small amounts of | deuterium / tritium gas inside the primary fission bom |
| The small amount of heavy | deuterium and tritium in this test fused, but its role |
| amount of heavy isotopes of liquid hydrogen ( | deuterium and tritium) placed at its center. |
| nization energy are within 0.5% of hydrogen, | deuterium, and tritium. |
| wer from a plasma composed of equal parts of | deuterium and tritium. |
| sed on highly enriched uranium combined with | deuterium and tritium. |
| However, when | deuterium is used instead of hydrogen, the deuterium f |
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