ライフサイエンスコーパス: low-melting

1 by using monodentate dibutyl ether with both low melting and high boiling points as the sole solvent.

2 , a significant push (repulsion) between the low-melting and high-melting lipids, and a significant p

3 ect of fluoride ions on Nd metal recovery in low-melting chloride-based electrolytes, promising effic

4 the initial stages of arc rifting due to the low melting degree and being consumed during the process

5 A series of six low-melting DNA hairpins containing all or part of the 5

6 ons created by Pfu DNA polymerase in a 96-bp low melting domain of a human mitochondrial sequence des

7 e amorphous phase are achieved, as well as a low melting energy.

8 Metal flux synthesis in a low-melting eutectic mixture of lanthanum and nickel has

9 imited extent in Ag 0.51K 0.42Na 0.07NO 3, a low-melting eutectic mixture of silver, potassium, and s

10 poly(triazine imide).LiCl (PTI/LiCl) with a low-melting FeCl(2)/KCl flux, followed by anaerobic rins

11 The low-melting ferritin subdomains are pores, based on perc

12 The observation of low-melting ferritin subdomains by CD spectroscopy (melt

13 nges were associated with an increase in the low-melting fraction and the crystal lamellar thickness,

14 Palm olein, a low-melting fraction of palm oil, and soy oil can be com

15 tract alone or combined with high-melting or low-melting lecithins.

16 g lipids, and a significant push between the low-melting lipids and cholesterol.

17 the solubilization, whereas the addition of low-melting lipids promoted it.

18 in bilayers composed of high-melting lipids, low-melting lipids, and cholesterol, corresponds to a st

19 trate that combining a range of linkers with low-melting metal halide (hydrate) salts leads directly

20 opportunities for direct BaTiO3 formation on low-melting or reactive materials (e.g., plastics, cloth

21 ical relations with volumes of ions in these low-melting organic salts.

22 f cholesterol and an exchangeable mimic of a low-melting phospholipid in liquid-disordered bilayers c

23 the regular battery configuration due to its low melting point (180.5 degrees C) and high reactivity,

24 iodegradable Mg alloys is challenging due to low melting point (650 degrees C), occurrence of chatter

25 ed plate like scales consisting of layers of low melting point alloy (LMPA) phase change materials fu

26 in a tapered glass micropipet filled with a low melting point alloy.

27 ionic conductivity, low solvation energy and low melting point and form an anion-derived inorganic in

28 if one or more of the powder reactants has a low melting point and low thermal effusivity, it is poss

29 iously available Cd precursors, owing to the low melting point and robust thermal stability.

30 The outermost metal layers form a low melting point Bi(33.7)In(66.3) solder shell (72 degr

31 irrespective of whether this was the high or low melting point component of the mixture.

32 at the large size (5-50 microm in diameter), low melting point gallium droplets can be used as an eff

33 the native interfacial metal oxide layer of low melting point metal precursors (group III and IV) in

34 ZITO) because of its superior volatility and low melting point of 64 degrees C.

35 Further, the material features a low melting point of around 65 degrees C, which enables

36 e induced by heating for metallic NPs with a low melting point or a high organic content.

37 int) solvents need to be mixed with suitable low melting point supporting electrolytes (e.g., ionic l

38 ted to surface restructuring caused by their low melting point upon laser irradiation.

39 s operating at low temperatures due to their low melting point.

40 the beads are coated with a solder having a low melting point; (iv) the polymer rods-with embedded b

41 These include the use of bismuth for low-melting point alloys for shells, thin-walled aluminu

42 g nanowire via a liquid catalyst, commonly a low-melting point eutectic alloy.

43 ion high-temperature materials to bypass the low-melting point limitation of eutectic alloys and diff

44 n of several functional particles, including low-melting point metallic particles, self-propelling Ja

45 ype of frit is found superior to one made of low-melting point poly(styrene-co-divinylbenzene) beads.

46 try approach for chemical depth profiling of low-melting point, high surface roughness SnAg solder bu

47 Binary mixtures of liquid metal (LM) or low-melting-point alloy (LMPA) in an elastomeric or flui

48 acids were present on powder surface whereas low-melting-point fatty acids remained within powder par

49 High-melting-point and low-melting-point lipids were tested to modulate their p

50 a distillation-like process is observed: the low-melting-point metal (Pt) bleeds out and the increasi

51 Here we show low-melting-point metal alloys containing iron dispersio

52 We demonstrate that low-melting-point metals, such as Ga, can effectively pr

53 The design of this conductive, low-melting-point sulfur iodide material represents a su

54 a low temperature of 650 degrees C by using low-melting-point ternary molten salts CaCl2 -MgCl2 -NaC

55 -point, high-voltage metal (antimony) with a low-melting-point, low-cost metal (lead) advantageously

56 are highly inviscid liquids characterized by low melting points and high solubility of rare earth ele

57 Thermal analysis confirmed low melting points and high stability, supporting their

58 The low melting points and high thermal stabilities of PILs

59 icient strengths at high temperatures due to low melting points and microstructural instabilities.

60 low vapor pressure, high thermal stability, low melting points, and ability to promote a favorable s

61 pressures, exceptional thermal stabilities, low melting points, as well as provide a favorable envir

62 a class of non-molecular ionic solvents with low melting points.

63 utions: (i) negligible vapor pressures; (ii) low melting points; (iii) high thermal stabilities.

64 Although known systems yielded amorphous or low-melting polymers, the "sandwich" alpha-diimines 3-6

65 ields of new thermally stable and relatively low melting quaternary salts.

66 These waves weaken the Amundsen Sea Low, melting sea ice due to enhanced shortwave radiation

67 plasmonically active, and is a component in low-melting solders and solid-state lubricants.

68 hibit an unusual confluence of exceptionally low melting temperature (175 degrees C) and inhibited cr

69 high melting temperature (saturated) lipids, low melting temperature (usually unsaturated) lipids, an

70 OPH) on the cell surface were immobilized in low melting temperature agarose on a nylon membrane and

71 the poor chemical recyclability but also the low melting temperature and mechanical performance of th

72 (NaCl) crystals, a well-studied sample with low melting temperature and quantum super-shells of clus

73 lenebis(acetamide)], which features a record-low melting temperature for a three-dimensional metal-or

74 nary lipid bilayers composed of a high and a low melting temperature lipid and cholesterol represent

75 main features that provide insights into the low melting temperature of alpha1(V)alpha2(V)alpha3(V) h

76 Because of the relatively low melting temperature of the 20-mer hairpin (341 K (68

77 we show this inference is incorrect for the low melting temperature phosphatidylcholines abundant in

78 h is 8 (DLPC/DAPC), the concentration of the low melting temperature phospholipid component in the so

79 hase domains, the local concentration of the low melting temperature phospholipid component increases

80 an intrinsic lack of strength, ductility and low melting temperature severely restricts practical app

81 mposed of ternary mixtures of a lipid with a low melting temperature, a lipid with a high melting tem

82 howed abnormal electrophoretic migration and low melting temperature.

83 a template walking mechanism using a pair of low-melting temperature (Tm) solid-surface homopolymer p

84 bilayers composed of a ternary mixture of a low-melting temperature lipid, a high-melting temperatur

85 ane (Ni, Pt, Pd), when dissolved in inactive low-melting temperature metals (In, Ga, Sn, Pb), produce

86 mically active, low-thermal conductivity and low-melting temperature semiconducting tellurium filamen

87 Herein we report glass formation for low-melting-temperature 1-MeHa(2)PbI(4) (1-MeHa = 1-meth

88 The low melting temperatures of these compounds are the resu

89 Ionic liquids (ILs, organic salts with low melting temperatures) and deep eutectic solvents (DE

90 of complex crystal structures with unusually low melting temperatures, reaching as low as 300 K at 11

91 ed have potential applications, due to their low melting temperatures, wide temperature ranges, and s

92 is most favorable in thinner membranes with low melting temperatures.

93 lted in amorphous materials or polymers with low melting temperatures.

94 of bis(acetamide)-based networks with record-low melting temperatures.

95 A series of low-melting, thermally stable cadmium metal-organic chem