Abstract: Tagging agents, including fluorescent monomers, which may lack polymerizable double bonds. Anti-scalant polymer compositions that include a copolymer of a tagging agent and an anti-scalant monomer. Methods for synthesizing tagging agents, anti-scalant polymer compositions, and detecting an anti-scalant polymer composition.

Abstract: The present invention provides a method for determining concentration of polyelectrolyte or phosphonate in a sample comprising polyelectrolyte or phosphonate in low concentrations. The method comprises admixing the sample with a reagent comprising a lanthanid(lll) ion; admixing the sample with silica; allowing the polyelectrolyte or phosphonate in the sample to interact with the reagent comprising the lanthanide(lll) ion and the silica; exciting the sample and detecting a sample signal deriving from the lanthanide(lll) ion by time-resolved fluorescence measurement; and determining the concentration of the polyelectrolyte or phosphonate in the sample by using the detected sample signal.

Abstract: The present invention provides a method for determining concentration of polyelectrolyte or phosphonate in a sample comprising polyelectrolyte or phosphonate in low concentrations. The method comprises admixing the sample with a reagent comprising a lanthanid(lll) ion; admixing the sample with silica; allowing the polyelectrolyte or phosphonate in the sample to interact with the reagent comprising the lanthanide(lll) ion and the silica; exciting the sample and detecting a sample signal deriving from the lanthanide(lll) ion by time-resolved fluorescence measurement; and determining the concentration of the polyelectrolyte or phosphonate in the sample by using the detected sample signal.

Abstract: The present invention relates to utilization of lanthanide time resolved fluorescence for determining concentration of trivalent metal ions in a sample. In the method sample comprising trivalent metal ions is admixed with a reagent comprising a lanthanide (lll) ion and a chelating agent. The trivalent metal ion in the sample is allowed to interact with the reagent comprising the lanthanide (lll) ion and the chelating agent, followed by exciting the sample and detecting a signal deriving from the lanthanide (lll) ion, and determining the concentration of the trivalent metal ion in the sample by using the detected signal.

Abstract: The present invention relates to a method for determining hydrolysis degree and charge density of polyelectrolyte or phosphonate in a sample. In the method the sample is mixed with a reagent comprising a lanthanide(lll) ion. The mixture is excited at an excitation wavelength and a signal deriving from the lanthanide(lll) ion is detected by using time-resolved fluorescence measurement, followed by determining the hydrolysis degree and the charge density of the polyelectrolyte or phosphonate by using the detected sample signal.

Abstract: The present invention relates to a method for determining concentration of phosphate in a sample method comprises mixing the sample with a lanthanide (III) chelate or with lanthanide (III) ion and a chelation agent; allowing the phosphate in the sample to interact with the lanthanide (III) chelate; or with the lanthanide (III) ion and the chelation agent; exciting the sample and detecting a sample signal deriving from the sample by using time-resolved luminescence measurement; and determining the concentration of the phosphate in the sample.

Abstract: The present invention relates to a cold-crystallizing material having high latent heat, and a method of using the present material for heat storing. The material of the invention comprises of a phase change material and an additive which is preferably a hydrophilic polymer matrix. Preferably, sugar alcohols, such as erythritol or D-mannitol, are used as the phase change material. The polymer of the invention is preferably cross-linked and ionic, i.e. a polyelectrolyte. PCM stores a high amount of heat energy while melting and releases the stored thermal energy by cold-crystallization. Compared to previously studied cold-crystallizing materials, the latent heat of the cold-crystallizing material of the invention is considerably higher, and cold-crystallization is more repeatable in successive melting-crystallization cycles. The material can be used for heat storing. Heat energy can be released from the material by a heat pulse on demand. The method is particularly suitable for long-term heat storing.

Abstract: The present invention relates to utilization of lanthanide time resolved fluorescence for determining total concentration of polyelectrolyte or phosphonate in a sample. In the method sample comprising two or more polyelectrolytes and/or phosphonates is acidified followed by admixing the acidified sample with a reagent comprising a lanthanide(lll) ion. The polyelectrolyte or phosphonate in the sample are allowed to interact with the reagent comprising the lanthanide(lll) ion, followed by exciting the sample and detecting a signal deriving from the lanthanide(lll) ion, and determining the concentration of the polyelectrolyte or phosphonate in the sample by using the detected signal.

Abstract: The present invention relates to utilization of lanthanide time resolved fluorescence for determining silica concentration. In the method sample comprising silica is admixed with a reagent comprising a lanthanide (III) ion and optionally a chelating agent, silica in the sample is allowed to interact with the reagent comprising the lanthanide (III) ion, followed by exciting the sample and detecting a signal deriving from the lanthanide (III) ion, and determining the concentration of the silica in the sample by using the detected signal.

Abstract: The present invention relates to a cold-crystallizing material having high latent heat, and a method of using the present material for heat storing. The material of the invention comprises of a phase change material and an additive which is preferably a hydrophilic polymer matrix. Preferably, sugar alcohols, such as erythritol or D-mannitol, are used as the phase change material. The polymer of the invention is preferably cross-linked and ionic, i.e. a polyelectrolyte. PCM stores a high amount of heat energy while melting and releases the stored thermal energy by cold-crystallization. Compared to previously studied cold-crystallizing materials, the latent heat of the cold-crystallizing material of the invention is considerably higher, and cold-crystallization is more repeatable in successive melting-crystallization cycles. The material can be used for heat storing. Heat energy can be released from the material by a heat pulse on demand. The method is particularly suitable for long-term heat storing.

Abstract: The invention relates to a liquid antiscalant composition for reducing calcium oxalate scale formation. The composition comprises a polyanionic antiscalant agent having a plurality of anionic groups, which antiscalant agent is selected from the group consisting of polyphosphates, polymers comprising at least one carboxylic group and any of their mixtures. The antiscalant composition further comprises magnesium ions. The invention further relates to use of the antiscalant composition for inhibiting and/or reducing formation of calcium oxalate scale in pulp and paper industry.