「-thermal」の共起表現一覧(1語右で並び替え)2ページ目
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delocalization can strongly contribute to the | thermal conductivity, which shows abrupt increase abo |
Liquid helium typically has poor | thermal conductivity, so convective currents associat |
high heat resistance, high electrical and/or | thermal conductivity, and low thermal expansion are n |
al groups, such as the modulus of elasticity, | thermal conductivity, thermal expansion, and work har |
e cubic phase of zirconia also has a very low | thermal conductivity, which has led to its use as a t |
ry of all types, derivative thermogravimetry, | thermal conductivity, thermomechanical analysis, and |
Here, k is the | thermal conductivity, ρ is the density and cp is the |
rning tires are heated and as they have a low | thermal conductivity, they are difficult to cool down |
scopic properties, such as mechanical motion, | thermal conductivity, electrical conductivity and vis |
ive to place diamonds on surfaces to increase | thermal conductivity, and as an intermediate layer to |
at sink performance is a function of material | thermal conductivity, dimensions, fin type, heat tran |
onfers high mechanical strength and very high | thermal conductivity. |
l conductivity and related phenomena like the | thermal conductivity. |
ore DAPPI only works well for surfaces of low | thermal conductivity. |
history, Qt is the heat flow history and k is | thermal conductivity. |
f material that have a high heat capacity and | thermal conductivity. |
ifference over a piece of material with known | thermal conductivity. |
It has a large internal surface area and good | thermal conductivity. |
ngside other properties such as viscosity and | thermal conductivity. |
thermoelectric material, partly due to a low | thermal conductivity. |
Thermal conductivity: 0.14 W·cm−1·K−1 | |
Thermal conductivity: 16.5 W·m−1·K−1 | |
It is used as a | thermal conductor, an electrical conductor, a buildin |
drums allow for additional heat retention and | thermal consistency in the rolled piece, which in tur |
The overall | thermal constant (K) for P. terraenovae is 240.2 ± 9. |
temperatures T1 and T2 are brought in perfect | thermal contact, the temperature at the contact surfa |
all times for semi-infinite bodies in perfect | thermal contact. |
owing on from the above, it is possible (in a | thermal context) to regard entropy as an indicator or |
Fractures due to tension can occur due to | thermal contraction as rocks cool (with columnar basa |
g the frozen hydrazine fuel tank using SOHO's | thermal control heaters began on August 12. |
Passive | thermal control was achieved through the use of louvr |
ctric machinery, office automation equipment, | thermal control film for satellites, Printed circuit |
company will provide "communications, power, | thermal control and pointing services" but the power, |
ressure of 7.5 psi (51.7 kPa) and use passive | thermal control to keep temperatures at an average of |
Thermal control was planned to be achieved by fifty s | |
by testing life support, radiation shielding, | thermal control and communications capabilities." |
ate, increased battery capacity, and a better | thermal control system. |
Thermal Control System - Sistema Obespecheniya Teplov | |
Thermal control was planned to be achieved by a large | |
nts, and the module was provided with its own | thermal control, television transmission, and telemet |
Thermal control: Passive | |
carbon-coated radiators for | thermal control; |
ratory ovens are ovens for high-forced volume | thermal convection applications. |
This | thermal conversion is relatively slow because it is s |
In presence of radiative or | thermal cooling effects, the CENBOL may start to osci |
nalysis indicated the system developed a warm | thermal core; as a result, it was re-classified as Tr |
Thermal coupling of two organocopper compounds is als | |
aft's orbit change due to the mass release of | thermal covering whose attachment failed. |
gas, refinery off-gas and gas from cokers and | thermal crackers are good sources. |
e 1970s 1-hexene was also manufactured by the | thermal cracking of waxes. |
The Shukhov cracking process is a | thermal cracking process invented by Vladimir Shukhov |
Shukhov designed and built the first | thermal cracking techniques important to the petroche |
In 1927, Koch developed a more efficient | thermal cracking process for turning crude oil into g |
also industrially useful, is also prepared by | thermal cracking of hydrocarbons. |
This technology has been eclipsed by the | thermal cracking of 1,2-dichloroethane. |
the 1970s, 1-octene was also manufactured by | thermal cracking of waxes, whereas linear internal oc |
It can be also manufactured by | thermal cracking of ammonia in an ammonia cracker or |
Standard Oil of Indiana to purchase the Cross | thermal cracking process. |
Thermal cracking at 400-500 °C and 10 MPa yields viny | |
This is usually done by | thermal, cross linking or desolvation techniques, to |
E-Beam vs. | Thermal Cure |
For conductors, a significant portion of the | thermal current is carried by the electrons. |
To see an actual example of | Thermal Cycle Metal . |
This resulted in a more efficient | thermal cycle, yielding more shaft horsepower for a g |
It requires less force to stop a vehicle with | thermal cycled brakes. |
When applied quickly to avoid accidents, | thermal cycled brakes reduce swerve and skid because |
by HDA, whereas PCR reactions carried out in | thermal cycler that can hold multi-well sample plates |
e selling point that HDA negates the use of a | thermal cycler and therefore allows research to be co |
Figure 1a: A | thermal cycler for PCR |
sothermic temperature that does not require a | thermal cycler. |
Special | thermal cyclers are used that monitor the amount of p |
tion thereby obviating the need for expensive | thermal cyclers. |
Thermal cycling lessens the vehicle brakes' imperfect | |
s in temperature, such as storage at -80C and | thermal cycling. |
bsolute reach 45 °C, low rainfall and a large | thermal daily. |
a living tissue precisely without causing any | thermal damage to surrounding area. |
Ball's formula method of | thermal death time would become the standard of the U |
account of experiments made to determine its | thermal death point. |
Next, the | thermal decarboxylation takes place through the acid |
The | thermal decomposition of ammonium salts is a relative |
Methods for dehalogenating PoCl4 include | thermal decomposition at 300 °C, reduction of cold, s |
Very pure uranium can be produced through the | thermal decomposition of uranium halides on a hot fil |
It is currently studied through | thermal decomposition by calculating the different le |
or the decarboxylated derivatives obtained by | thermal decomposition of any of the naturally occurri |
This test relies on the | thermal decomposition of these trihydrides to the met |
The | thermal decomposition product in air above 300C is Co |
pure synthetic Moissanite has been made from | thermal decomposition of the preceramic polymer poly( |
The | thermal decomposition of [NH4]2[MoS4] leads to molybd |
also be synthesized on a smaller scale by the | thermal decomposition of trimethylammonium tetrapheny |
gen-bridged dimer after evaporation and until | thermal decomposition into chlorine perchlorate, Cl2O |
ry scale, PhF is conveniently prepared by the | thermal decomposition of the benzenediazonium tetrafl |
repared by reacting F2 or HF with Ga2O3 or by | thermal decomposition of (NH4)3GaF6.GaF3 is virtually |
dical reactions involving pyrolysis and other | thermal decomposition processes; and … the kinetics o |
irst synthesized tetrachloroethene in 1821 by | thermal decomposition of hexachloroethane. |
It can also be prepared directly by | thermal decomposition of pentose-containing materials |
jectured to be a fleeting intermediate in the | thermal decomposition of certain oxalates and certain |
Calcium oxide is usually made by the | thermal decomposition of materials such as limestone, |
Thermal decomposition, or thermolysis, is a chemical | |
g the desired product from the pure adduct by | thermal decomposition. |
le (N2), which is a product of the compounds' | thermal decomposition. |
It is highly resistant to | thermal degradation as well as attack by both organic |
The study of | thermal degradation and antioxidant stability in the |
Thermal degradation of the vinyl backbone can occur t | |
d as light stabilizers, it can also stabilize | thermal degradation. |
Anhydrous PrCl3 can be made by | thermal dehydration of the hydrate at 400 °C in the p |
It was first prepared by | thermal dehydration. |
g the need to add enzyme after every cycle of | thermal denaturation of the DNA. |
in a pure form for further concentrating and | thermal denitration to UO3, named Orange Oxide by the |
Thermal depolymerisation differs in that it contains | |
Thermal depolymerisation is similar to other processe | |
The | thermal depolymerization or thermal conversion proces |
An example for such an optimized | thermal desalination cycle is the multiple-effect hum |
rease in depth is used in the Low Temperature | Thermal Desalination (LTTD) to flash evaporate the wa |
BTX's | thermal design specifies a particular processor locat |
tus are designed to dissipate power up to the | Thermal Design Power, rather than maximum power, and |
oil from Penny's Bay was transferred here for | thermal desorption to separate the Volatile Organic C |
Thermal desorption spectroscopy (TDS), also known as | |
The main desorption mechanism in DAPPI is | thermal desorption due to rapid heating of the surfac |
A Leslie cube (left) and a | thermal detector (right) |
When the cube is filled with hot water, the | thermal detector (on the far right in the figure), sh |
a Schwarzinger and Heinz Falk, Concerning the | Thermal Diastereomerization of the Green Fluorescent |
other producing steady long burn, though has | thermal difficulties, CG shift. |
e author), using a beryllium oxide plate as a | thermal diffuser (BeO has a very high thermal conduct |
er Lewis recommended construction of the S-50 | thermal diffusion plant developed by Philip Abelson o |
rankel, S Phillips, “Elementary Derivation of | Thermal Diffusion,” Physical Review, Volume 57, Numbe |
where α is the | thermal diffusivity and D is the mass diffusivity. |
dimensionless number defined as the ratio of | thermal diffusivity to mass diffusivity. |
α is the | thermal diffusivity |
α: | thermal diffusivity, (SI units: m²/s) |
, D the mass diffusion coefficient, and α the | thermal diffusivity, |
ntrinsic physical stability factors, like the | thermal dilatation of the core, or the increased reso |
perspiration; consequent decreased epidermal | thermal dissipation leading to warm, blotchy, or red |
Thermal dissolution is a hydrogen-donor solvent refin | |
y in the world, and may be the only remaining | thermal distillation refinery, all other refineries h |
The | thermal distribution of density of photons follows fr |
he treatment, and monitoring temperatures and | thermal dose in real time during the treatment. |
Atmospheric | thermal ducting is often more intense at UHF, because |
plicated emission spectrum, and includes both | thermal dust emission and spinning dust emission. |
Therefore more often than not one has to use | thermal dynamical or macroscopic techniques to see th |
nd mass, power and mass for fuel cells, solar | thermal dynamics, radioisotope, nuclear reactor (if o |
The | thermal effects of the incident IR radiation can be f |
It showed that the main | thermal effects of impoundment and regulation have be |
h was shown to be most likely due to on-board | thermal effects and reflection of the generated radia |
bly more complex and varied than are blast or | thermal effects and are subject to considerable misun |
e working fluid has no bearing on the maximum | thermal efficiencies of the pseudo Stirling cycle. |
Index of | Thermal Efficiency - #41 Team Elite |
It has a | thermal efficiency of 53%. |
Index of | Thermal Efficiency - #6 Martini Racing Porsche System |
Index of | Thermal Efficiency - #59 Aston Martin Racing |
The overall | thermal efficiency of TOSCO II process is low because |
Index of | Thermal Efficiency - #45 Porsche Kremer Racing Team |
e to the lower installation price, the higher | thermal efficiency and less maintenance. |
Index of | Thermal Efficiency - #31 Jean-Philippe Grand |
the regenerator), a device for improving the | thermal efficiency of a variety of processes, obtaini |
Index of | Thermal Efficiency - #44 Team Lotus Engineering |
The station has a | thermal efficiency of 49%. |
Index of | Thermal Efficiency - #45 Autombiles Deutsch et Bonnet |
Thermal efficiency or Fuel efficiency, useful heat an | |
e effect (quality) of that gas stream and the | thermal efficiency of the process. |
,and had a high availability, load factor and | thermal efficiency when compared with most stations s |
in Low Speed Diesels the CWF has resulted in | thermal efficiency rating rivaling that of Combined C |
ingle-cylinder gasoline engine found that the | thermal efficiency of burning dimethylfuran is simila |
This improves | thermal efficiency and could potentially allow hydrog |
Index of | Thermal Efficiency - #34 Sunbeam Talbot |
The | thermal efficiency of the cycle is the ratio of the w |
se include improved fuel technology, superior | thermal efficiency, passive safety systems and standa |
The process is characterized by the high | thermal efficiency, but due to the addition of air in |
n the industry due to its excellent record of | thermal efficiency. |
ace coated tempered glass which will increase | thermal efficiency. |
ter responses, better performance, and better | thermal efficiency. |
Same as the | thermal efficiency. |
A material's | thermal effusivity is a measure of its ability to exc |
In Thermodynamics, the | thermal effusivity of a material is defined as the sq |
The Holyrood | Thermal Electric Generating Station built by Newfound |
exceeding 166,000 MW in over 90 countries for | thermal electric and hydroelectric plants. |
oadly three types of decomposition reactions: | thermal, electrolytic and catalytic. |
It says "released as a large amount of | thermal, electromagnetic and kinetic energy". |
The problem with using | thermal electrons to carry heat is the fact that, due |
Thermal ellipsoid model of the molecular cell of dode | |
A | thermal ellipsoid model of the coordination environme |
Thermal ellipsoids can be defined by a tensor, a math | |
Thermal ellipsoids, more formally termed atomic displ | |
The Advanced Spaceborne | Thermal Emission and Reflection Radiometer (ASTER), a |
ASTER (Advanced Spaceborne | Thermal Emission and Reflection Radiometer) is a Japa |
November 2006, the facility also operated the | Thermal Emission Spectrometer (TES) aboard the spacec |
ASTER (Advanced Spaceborne | Thermal Emission and Reflection Radiometer) |
ming announced a detection of strong infrared | thermal emission from the transiting extrasolar plane |
instruments based at the facility include the | Thermal Emission Imaging System (THEMIS) on NASA's Ma |
ments is to monitor clouds and to measure the | thermal emission (cooling) of the Earth. |
high resolution is necessary to separate out | thermal emission from the sources' large-scale hot-ga |
The | Thermal Emission Spectrometer (TES) is an instrument |
-ray emission from the source is dominated by | thermal emission from a rich cluster of galaxies. |
temperature to be determined, assuming it is | thermal emission from the surface of a neutron star. |
telescopes where an X-ray spectrum typical of | thermal emission from a cooling neutron was observed. |
ments measure (naturally-occurring) microwave | thermal emission from the limb (edge) of Earth's uppe |
This should not be confused with | thermal emissivity, which is a spectrum-dependent abi |
Thermal emittance is radiant emittance of heat. | |
Determining the | thermal emittance and solar reflectance of building m |
d reflective metal roofs usually have a lower | thermal emittance than other choices. |
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