A method for providing an image on or in a substrate is provided, and comprises applying to the substrate: (i) ammonium octamolybdate (AOM) in the form of the alpha-isomer, obtainable by thermal decomposition of ammonium molybdate at 215-225° C. for 180 mins, and which has an anhydrous loss on ignition in the range 8.00 to 8.80; or (ii) a composition comprising ammonium octamolybdate as defined in (i), and a binder; followed by irradiation. Also provided are liquid ink compositions comprising AOM as defined above, and a binder.

A method for providing an image on or in a substrate is provided, and comprises applying to the substrate: (i) ammonium octamolybdate (AOM) in the form of the alpha-isomer, obtainable by thermal decomposition of ammonium molybdate at 215-225° C. for 180 mins, and which has an anhydrous loss on ignition in the range 8.00 to 8.80; or (ii) a composition comprising ammonium octamolybdate as defined in (i), and a binder; followed by irradiation. Also provided are liquid ink compositions comprising AOM as defined above, and a binder.

The invention provides a method for reducing impurities from roasted molybdenum concentrate (RMC), comprising: performing a first treatment in a first reactor, on a portion of the RMC forming a first treated suspension, the first treatment comprises adding the portion of the RMC to a water-solution, wherein the first treated suspension has a temperature from 10° C. to 100° C. and a first pH value of from 2.1 to 5.0; performing a second treatment in a second reactor on a portion of the first treated suspension, the second treatment comprises adding the portion of the first treated suspension to an acid solution to form the second treated suspension, wherein the portion of the first treated suspension has a temperature <70° C., and wherein the second treated suspension has a second pH value between 1.5 and the first pH value; and separating a portion of the second treated suspension from the reactors.

The present invention relates to a lubricant containing molybdenum sulfide particles, and the molybdenum sulfide particles contain molybdenum disulfide having a 3R crystal structure. The present invention relates to a lubricating composition containing molybdenum sulfide particles, which are the lubricant, and a base oil which is a mineral oil, a synthetic oil, or a partially synthetic oil.

The preparation method according to the present disclosure is to easily prepare hexagonal molybdenum oxide (h-MoO.sub.3) having a nanorod shape even in a low temperature precipitation reaction at atmospheric pressure without applying hydrothermal synthesis under high temperature and high pressure conditions. The hexagonal molybdenum oxide (h-MoO.sub.3) nanorods prepared therefrom can be properly mixed with carbon-based conductive materials such as carbon nanofiber, and thus can be usefully used as an anode material for a pseudocapacitor.

The preparation method according to the present disclosure is to easily prepare hexagonal molybdenum oxide (h-MoO.sub.3) having a nanorod shape even in a low temperature precipitation reaction at atmospheric pressure without applying hydrothermal synthesis under high temperature and high pressure conditions. The hexagonal molybdenum oxide (h-MoO.sub.3) nanorods prepared therefrom can be properly mixed with carbon-based conductive materials such as carbon nanofiber, and thus can be usefully used as an anode material for a pseudocapacitor.

Processes for producing supported zinc dimolybdate hydroxide/silica complexes include the steps of reacting a zinc compound (such as zinc oxide) and molybdenum trioxide in an aqueous system to form a reaction mixture, and contacting the reaction mixture with silica to form the supported zinc dimolybdate hydroxide/silica complex. The resulting supported zinc dimolybdate hydroxide/silica complexes contain silica and zinc dimolybdate hydroxide at an amount in a range from 3 to 20 wt. % zinc, and generally, at least 80 wt. % of the zinc dimolybdate hydroxide is present in the form Zn.sub.3Mo.sub.2O.sub.8(OH).sub.2. These supported zinc dimolybdate hydroxide/silica complexes are useful in polymer compositions, such as PVC-based and epoxy-based formulations.

A method of making an atomic layer nanoribbon that includes forming a double atomic layer ribbon having a first monolayer and a second monolayer on a surface of the first monolayer, wherein the first monolayer and the second monolayer each contains a transition metal dichalcogenide material, oxidizing at least a portion of the first monolayer to provide an oxidized portion, and removing the oxidized portion to provide an atomic layer nanoribbon of the transition metal dichalcogenide material. Also provided are double atomic layer ribbons, double atomic layer nanoribbons, and single atomic layer nanoribbons prepared according to the method.

The present disclosure provides a ratiometric fluorescent probe, a preparation method thereof, and an application in detection of hydrogen peroxide. In the present disclosure, MoO.sub.x QDs (nanoenzymes) and Co/Zn-MOFs both have catalytic activity, and the large specific surface area and porous structure of Co/Zn-MOFs can provide more binding sites for the contact between nanoenzymes and substrates. Moreover, Co/Zn-MOFs have high catalytic activity similar to natural enzymes. When nanoenzymes with fluorescent properties encounter Co/Zn-MOFs with similar catalytic activity, they will collide with a spark of “synergy catalysis”, and the fusion of the two plays a role of synergy catalysis; in addition, the uniform cavity of Co/Zn-MOFs can provide “hosts” for nanoenzymes, and Co/Zn-MOFs provide “anchors” for MoO.sub.x QDs, avoiding the aggregation of MoO.sub.x QDs and enhancing the stability of the probe.

The present disclosure provides a ratiometric fluorescent probe, a preparation method thereof, and an application in detection of hydrogen peroxide. In the present disclosure, MoO.sub.x QDs (nanoenzymes) and Co/Zn-MOFs both have catalytic activity, and the large specific surface area and porous structure of Co/Zn-MOFs can provide more binding sites for the contact between nanoenzymes and substrates. Moreover, Co/Zn-MOFs have high catalytic activity similar to natural enzymes. When nanoenzymes with fluorescent properties encounter Co/Zn-MOFs with similar catalytic activity, they will collide with a spark of “synergy catalysis”, and the fusion of the two plays a role of synergy catalysis; in addition, the uniform cavity of Co/Zn-MOFs can provide “hosts” for nanoenzymes, and Co/Zn-MOFs provide “anchors” for MoO.sub.x QDs, avoiding the aggregation of MoO.sub.x QDs and enhancing the stability of the probe.