Nianxi Wang

Title: Nianxi Wang: Innovator in CO2 Reaction Testing Methods

Introduction

Nianxi Wang is a notable inventor based in Chengdu, China, known for his innovative work in evaluating the effects of CO2 reaction rates on acid rock plates. With one patented invention to his name, Wang has made significant strides in the field of testing methodologies, contributing to advancements in geological and environmental studies.

Latest Patents

Wang's most recent patent focuses on a comprehensive testing method aimed at evaluating the reaction rates of CO2 with acid rock plates. The patented technology introduces a sophisticated testing device that includes essential components such as an acid fluid conveying unit, a CO2 conveying unit, a mixing tank, a plate holder, a recycling fluid tank, and a vacuum pump. The design of the mixing tank comprises multiple inlets and outlets, allowing for a streamlined evaluation process. This invention represents a significant advancement in the way reactions are assessed, providing a reliable setup for future research in this area.

Career Highlights

Wang is affiliated with Southwest Petroleum University, where he continues to develop and expand his research in the field of petroleum engineering and geochemistry. His dedication to innovation in testing methods demonstrates his commitment to enhancing the understanding of chemical reactions in geological formations.

Collaborations

Throughout his career, Nianxi Wang has worked alongside esteemed colleagues such as Jianchun Guo and Xiao Li. These collaborations have fostered a creative environment where innovative ideas can flourish, furthering research and development in the fields related to their expertise.

Conclusion

Nianxi Wang stands out as a passionate inventor whose work on CO2 reaction testing methods has the potential to significantly influence both academic research and industrial applications. His innovative approaches exemplify the importance of continuous advancement in scientific methodologies, and his contributions pave the way for future breakthroughs in the evaluation of geological interactions.