I. Basic Information

　　Project Subject: Institute of High Energy Physics, Chinese Academy of Sciences

 Beijing Huairou Science City Construction and Development Co., Ltd.

 Category: First batch of cross-research platforms

　　Location: Central Area of Huairou Science City

 Area: 44 mu

 Building area: 30000 m2

 Total investment: 427.52 million yuan

　　Subject orientation: Material science

 Rendering of Clean Energy Materials Testing, Diagnosis and R&D Platform

　　II. Main Contents

 Project introduction: The Clean Energy Materials Testing, Diagnosis and R&D Platform will address three key areas: energy storage, energy conversion and energy-efficient use. The platform is capable of providing real-time and accurate analysis of the space, composition and physical and chemical properties from the atomic to the macroscopic scale. The platform is capable of conducting high-resolution in-situ and ex-situ testing of key materials, devices and systems in clean energy technology, with protection provided by an inert atmosphere. The platform is capable of performing non-destructive and destructive diagnosis and failure analysis, as well as test verification of major clean energy materials and devices currently in development and in use. It can also conduct forward-looking research and development of clean energy technologies, with the potential to evolve into a national-level clean energy science and technology research center, innovation center, and technology transfer center for innovative and key technologies.

Upon completion, the platform will significantly bolster research and development of clean energy materials and devices in China, fostering the emergence of innovative and transformative clean energy technologies and expediting the transfer and transformation of clean energy technologies.

The platform is divided into five sub-platforms according to research directions and functions, namely the “Chemical Energy Storage Sub-platform”, “Physical Energy Storage Sub-platform” and “Solar Cell Sub-platform”, “Solid-State Lighting Sub-platform” and the “Research Sub-platform for Synchrotron Radiation Light Source Station for Clean Energy” scheduled for construction at a later date.

The independent functions of each sub-platform can greatly promote the in-depth development of research in various fields.

Sub-platforms can also be interconnected, mutually supportive and integrated. They can be closely integrated with high-energy synchrotron radiation sources and user devices with comprehensive extreme conditions to provide advanced and fully functional experimental conditions for comprehensive clean energy materials and device testing, diagnostic analysis and research.