Comparative Analysis of Two Different Techniques for Ridge Preservation Following Tooth Extraction: A Clinical and Radiographic Study.

Background: Ridge preservation following tooth extraction is essential for maintaining the alveolar bone structure and facilitating successful dental implant placement. Various techniques have been proposed for this purpose, but there remains a need for comparative analysis to determine their efficacy.

Materials And Methods: This clinical and radiographic study compared two different techniques for ridge preservation: Technique A and Technique B.

Phenolic Foam Preparation Using Hydrofluoroolefin Blowing Agents and the Toughening Effect of Polyethylene Glycol.

In this work, a new class of fourth-generation, zero ozone depletion potential, hydrofluoroolefin-based blowing agents were used to prepare phenolic foam. While hydrofluoroolefin blowing agents have been used previously to prepare polyurethane foams, few studies have been reported on their use in phenolic foams. We introduce an effective method for foam preparation using two low-boiling blowing agents, cis-1,1,1,4,4,4-hexafluoro-2-butene and trans-1,1,1,4,4,4-hexafluoro-2-butene, and their combinations with hexane.

Preparation and Characterization of Date Palm Bio-Oil Modified Phenolic Foam.

In this work, the potential of biomass-derived date palm bio-oil as a partial substitute for phenol in the phenolic resin was evaluated. Date palm bio-oils derived from date palm were used for the partial substitution of phenol in the preparation of phenolic foam (PF) insulation materials. Date palm waste material was processed using pyrolysis at 525 °C to produce bio-oil rich in phenolic compounds.

Comparison of Toughening Effects of Various Additives on Phenolic Foam.

Phenolic foams (PFs) are considered excellent insulation materials owing to their flame retardancy and low thermal conductivity. However, their mechanical properties often lag behind those of other polymeric insulation materials. To fully exploit their properties and broaden end-use applications, the mechanical properties of PFs must be enhanced.

Bio-Based Alternatives to Phenol and Formaldehyde for the Production of Resins.

Phenol-formaldehyde (PF) resin continues to dominate the resin industry more than 100 years after its first synthesis. Its versatile properties such as thermal stability, chemical resistance, fire resistance, and dimensional stability make it a suitable material for a wide range of applications. PF resins have been used in the wood industry as adhesives, in paints and coatings, and in the aerospace, construction, and building industries as composites and foams.