The systematic under-valuation of nature is creating growing risks for the global financial system, raising the prospect of a “Nature’s Minsky Moment” - a sudden repricing of assets triggered by ecosystem collapse. A new peer-reviewed study shows how recent advances in NatureFinTech now make it possible to measure ecosystem integrity at scale, enabling nature to be financed as critical infrastructure and laying the groundwork for a new asset class called Nature Equity.

A research paper by scientists at Wenzhou Medical University developes a mannose-modified pH/glutathione (GSH) dual-responsive nano-delivery system (MPP@IKE-aPD-1/diABZI) that synergistically activates ferroptosis and immune responses to achieve efficient antitumor therapy.

The accelerated evolution of space technology has elevated the importance of high power and lightweight attributes in satellite design. In response to the conflict between the demand for large-scale, high-power payloads and the need for lightweight, compact platforms, flexible space origami membrane structures have emerged as a potential solution. These structures possess the ability to overcome the limitations of traditional deployable mechanisms. Their geometric reconfiguration capabilities, characterized by high folding ratios, effectively satisfy the high-power performance demands.

A new study published in Big Earth Data evaluates ten satellite-based and reanalysis precipitation datasets available in Google Earth Engine using rain gauge observations across Czechia from 2001 to 2021. The results show that the gauge-adjusted GSMaP dataset provides the highest overall accuracy, while ERA5-Land performs well for long-term analyses despite systematic overestimation. The findings offer clear guidance for selecting reliable precipitation datasets for hydrological, climate, and environmental applications, particularly in regions with complex terrain.

Associate Professor Yuichiro Matsushita of Materials and Structures Laboratory, Institute of Science Tokyo, Mitsubishi Electric Corporation, Associate Professor Takahide Umeda of Institute of Pure and Applied Sciences, University of Tsukuba and Quemix Corporation  announced today that they have achieved the world’s first¹ elucidation of how hydrogen produces free electrons² through the interaction with certain defects³ in silicon. The achievement has the potential to improve how insulated gate bipolar transistors (IGBTs) are designed and manufactured, making them more efficient and reducing their power loss. It is also expected to open up possibilities for future devices using ultra-wide bandgap (UWBG) materials.⁴