ライフサイエンスコーパス: corrosive

1 rogen sulfide which is toxic, explosive, and corrosive.

2 droesterification catalyst makes the process corrosive.

3 lenging oxygen evolution reaction (OER) in a corrosive acidic environment.

4 of bimetallic oxide OER electrocatalysts in corrosive acidic environments.

5 ture and high pressure) in the presence of a corrosive acidic medium, and causing serious environment

6 s, removing the requirement to use extremely corrosive acids, thereby enabling the use of this method

7 o water and hydrogen; thus, the chemical and corrosive activity of water does not increase.

8 e (relative humidity = 90% at 85 degrees C), corrosive agent exposure, and proton irradiation.

9 burns and of late sequels after ingestion of corrosive agents, but long-term outcome is unknown.

10 rred in patients injured by the ingestion of corrosive agents.

11 a new platform to control the reactivity of corrosive air pollutants.

12 Under these conditions, a corrosive ambient such as laboratory air exacerbates the

13 Activity and stability promoters are often corrosive and add to the complexity of the system, makin

14 for alkene diazidation rely on the usage of corrosive and expensive oxidants or complicated electroc

15 However, its preparation requires the use of corrosive and hazardous chemicals, such as hydrofluoric

16 e separators, active material crossover, and corrosive and hazardous electrolytes.

17 nitric acid/sulfuric acid mixtures, are too corrosive and oxidizing to preserve structural integrity

18 red crude oils and oil sands, and are toxic, corrosive and persistent.

19 fferent from previous CMP slurries, in which corrosive and toxic chemical reagents are usually employ

20 eration of the thioamide requires the toxic, corrosive, and flammable gas H(2)S.

21 to rover components as brines can be highly corrosive, and to quantify the ability of the regolith a

22 The modified surfaces are stable to corrosive aqueous solutions and common organic solvents.

23 dheres to the metal surface protects it from corrosive atmospheres and carbon (carburization), thus a

24 mperature operation, and the minimization of corrosive attack through effective insulation.

25 sms and between microorganisms and metals in corrosive biofilms show promise for developing new techn

26 ging applications bring the IC closer to the corrosive body environment, raising reliability concerns

27 loading and reaction temperature, no use of corrosive Bronsted acids as well as toxic azeotropic sol

28 rganisms in culture are required to evaluate corrosive capabilities and mechanisms.

29 982 zinc-based pennies developed radiolucent corrosive changes within 24 hours.

30 onvenient, inexpensive, does not require any corrosive chemicals and provides specific detection of s

31 s, which makes them ideal for the storage of corrosive chemicals such as ammonia.

32 methods involve high-pressure processing and corrosive chemicals.

33 its benign nature free from strong acids and corrosive components, zinc-polyiodide flow battery is a

34 ely recyclable and does not involve toxic or corrosive components.

35 gh ORR activity and stability under a highly corrosive condition of 10 M NaOH at 80 degrees C, demons

36 frequently experiences seasonal exposure to corrosive conditions (Omegaar < 1) along the US West Coa

37 y convert methane into CH(3)Cl are run under corrosive conditions and typically yield a mixture of ch

38 ite could provide short-term amelioration of corrosive conditions at certain times of the year; howev

39 ling of carbon-enriched waters that generate corrosive conditions for local ecosystems.

40 oxygen evolution reaction (OER) under highly corrosive conditions such as in acidic proton exchange m

41 tolerance related to history of exposure to corrosive conditions.

42 nt types of oil, organic solvents, toxic and corrosive contaminants.

43 Importantly, electroactive and corrosive Desulfovibrio desulfuricans and Desulfovibrio

44 , remains scarce, particularly for naturally corrosive Eastern Boundary Upwelling systems (EBUs).

45 Past research has highlighted the corrosive effects of unemployment on health and health b

46 n important property for processes involving corrosive effluents (e.g., radioactive waste), was also

47 ectrochemical water splitting, often require corrosive electrolyte, limiting their performance stabil

48 irements, such as high chemical stability in corrosive electrolytes, good resistance to organic solve

49 been widely investigated as nontoxic and low-corrosive energy conversion devices with high energy and

50 functional properties of CrFe anodes in the corrosive environment of MOE are studied via empirical o

51 In the absence of a corrosive environment, brittle materials such as silicon

52 When metallic alloys are exposed to a corrosive environment, porous nanoscale morphologies spo

53 he simultaneous action of high temperatures, corrosive environments and radiation damage.

54 erials used for implant applications and the corrosive environments found in the human body, in combi

55 candidates for application in aggressive and corrosive environments.

56 l compatibility of ceramics with many highly corrosive environments.

57 toxic, irritating, extremely flammable, and corrosive features.

58 ocated) was directly linked to the switch to corrosive Flint River water from noncorrosive Detroit wa

59 Affective polarization is a corrosive force in American politics.

60 e rust expansion when concrete cracks due to corrosive forces.

61 e) the link between intergroup bias and more corrosive forms of social hostility.

62 ce gas H(2) (with negligible coproduction of corrosive gas HCl) and carbon materials using Ga as a li

63 This highly toxic and corrosive gas is produced by the reaction of acid-grade

64 als that transmit electrons while preventing corrosive gas molecules.

65 Boron trifluoride (BF(3) ) is a highly corrosive gas widely used in industry.

66 irreversibly or degrade on exposure to this corrosive gas(10,11).

67 separation of chemically challenging and/or corrosive gases, especially when designed to exhibit a h

68 the storage and capture of other noxious and corrosive gases.

69 s liquid-phase organometallic catalysts with corrosive halide-based cocatalysts to achieve high selec

70 he COFs were porous and chemically stable in corrosive, harsh environments for at least 1 week.

71 ue to its facile release of plasticizers and corrosive HCl gas.

72 lution to performing optical spectroscopy in corrosive, high-temperature melts but also provides impo

73 y due to uncontrollable dendrite growth, the corrosive hydrogen evolution reaction (HER) and decompos

74 al souring in oil reservoirs produces toxic, corrosive hydrogen sulfide through microbial sulfate red

75 The corrosive impact of ethnic antagonism on Republicans' co

76 July 2002 to December 2009, 36 patients with corrosive-induced upper gastrointestinal strictures in a

77 ded balloon dilations (EBD) in patients with corrosive-induced upper gastrointestinal strictures, eit

78 Corrosive injuries complicated with ES can be effectivel

79 he diagnoses of esophageal atresia (n = 26), corrosive injury (n = 8), leiomyomatosis (n = 5), and re

80 1,000 degrees C, and do not involve toxic or corrosive intermediates, are highly desirable because th

81 as possible alternatives to the volatile and corrosive iodide/triiodide redox couple commonly used as

82 en when exposed to harsh conditions, such as corrosive liquids, ultraviolet radiation, and freeze-tha

83 ructure despite physical contact with moving corrosive lithium metal is a demanding requirement.

84 of recycling and after suffering erosion by corrosive media.

85 n that enables spectroscopic measurements of corrosive melts.

86 e at the well-head using inexpensive and non-corrosive methods.

87 Hence, the need for an efficient real-time corrosive microbe monitoring technology is evident.

88 Early detection of corrosive microbes is pivotal for effective monitoring a

89 d is protected, and (3) reduced formation of corrosive microenvironments at lead surfaces in galvanic

90 corrosion, but new strategies for recovering corrosive microorganisms in culture are required to eval

91 unding electromagnetic field, and the highly corrosive molten salt electrolyte to deal with.

92 ery useful in investigating the structure of corrosive molten salts, such as the cryolite-based melts

93 alyst, is still facing challenges due to its corrosive nature and sluggish kinetics.

94 n Mn, a reaction that, because of the highly corrosive nature of Mn, to our knowledge has never befor

95 However, due to the corrosive nature of SO(2), conventional porous materials

96 design overcomes the challenges posed by the corrosive nature of the salts, allowing for an accurate

97 based salts is challenging due to the highly corrosive nature of these salts, which can degrade many

98 The complex, mobile, and corrosive nature of this fluid presents a fundamental ch

99 nd volatile hydrazoic acid intermediate, the corrosive nature of triflic acid, and the exothermic que

100 orm analytical measurements because of their corrosive nature, significant thermal convection and the

101 Owing to its inertness and non-corrosive nature, the Mg(CB11H12)2/tetraglyme (MMC/G4) e

102 laced in culture and art museums, due to its corrosive nature.

103 bustness of the mass spectrometer due to its corrosive nature.

104 s are precursors for biofuels but are highly corrosive necessitating further upgrading.

105 and decompose in the presence of caustic and corrosive NH(3).

106 O(3) burial to marine sediments beneath more corrosive North Pacific deep waters.

107 cal abrasion resistance even towards various corrosive oil/water mixtures (such as strong acid, alkal

108 thium salts dissolved in solvents are toxic, corrosive, or flammable.

109 lysis, as typically it involves expensive or corrosive oxidants or reaction media that are not amenab

110 Developing efficient and anti-corrosive oxygen reduction reaction (ORR) catalysts is o

111 study provides a useful tool for monitoring corrosive P. aeruginosa biofilm in aquatic environments,

112 ilm growth resulted in significantly greater corrosive pit density, with 15 and 47 pits mm(-2) in the

113 t optical approach that can be integrated in corrosive processes, was used to follow the unique finge

114 Corrosive properties of MgCl(2) hydrates must be address

115 nclude providing durability to leather, anti-corrosive properties to metals, and substrates for 3D pr

116 sh environments such as high temperature and corrosive reactants compared to the more conventional mu

117 roach to mitigate dendrite growth and reduce corrosive reactions through the design of ultrathin sele

118 essitating the use of moisture-sensitive and corrosive reagents.

119 easing the bond without high temperatures or corrosive solutions can be a barrier to applications inv

120 se dioxygen directly in lieu of toxic and/or corrosive stoichiometric oxidants.

121 metal has often been coupled with strong and corrosive sulfuric acids (2-3 M), leading to severe elec

122 be grown without the production of toxic and corrosive sulphide, should aid biochemical investigation

123 treated Flint River water was 8.6 times more corrosive than Detroit water in short-term testing, rele

124 medium is a mild acid that is not only less corrosive than popularly utilized oxidation media, but a

125 The raw bio-oil, however, is corrosive; therefore, employing it as fuel is challengin

126 high levels of which are toxic to humans and corrosive to equipment.

127 It is poisonous to catalysts and corrosive to metals and therefore needs to be removed.

128 h free chlorine that are normally considered corrosive to solder.

129 ic stability of these electrolytes, they are corrosive toward metallic battery components, which redu

130 The corrosive water also led to 1.3-2.2 times more water mai

131 l ecosystems, upwelling of nutrient-rich and corrosive water may also contribute to variability in pH

132 dent of increasing porosity from exposure to corrosive water or bioerosion.

133 wing fresh mineral surfaces to interact with corrosive waters and biota from Earth's surface, while s

134 igher resistance against dissolution in more corrosive waters.