Computer Science: In-Depth Description

Photo Credit: Massimo Botturi

Computer Science is the systematic study of computation, information, and automation, focusing on algorithmic processes, computational machines, and their application. Its primary goals are to understand the theoretical foundations of what can be computed, to design and implement hardware and software systems for processing information, and to apply computational thinking to solve complex problems across all domains of human endeavor.

Chemistry: In-Depth Description

Photo Credit: Artem Podrez

Chemistry is the scientific discipline dedicated to the study of matter—its composition, properties, structure, and the changes it undergoes during chemical reactions, as well as the energy that is released or absorbed during these processes. The primary goal of chemistry is to understand the behavior of matter at the atomic and molecular level and to use this understanding to discover, create, and manipulate new substances and processes.

What Is: Narcissism

Image Credit: Scientific Frontline / AI generated

The term "narcissism" is one of the most frequently deployed yet widely misunderstood concepts in the modern psychological lexicon. Rooted in the Greek myth of Narcissus—the youth who fell in love with his own reflection—its popular use is often pejorative, synonymous with simple vanity or selfishness. In clinical and research contexts, however, the construct is far more complex. Narcissism is not a binary attribute but a self-centered personality style that exists on a continuum, ranging from normal and adaptive traits at one end to a severe, pathological personality disorder at the other. 

UH calculates survival needs of deep-diving Hawaiian pilot whales

An aerial view of Hawaiʻi short-finned pilot whales at the surface.
Photo Credit: HIMB Marine Mammal Research Program

For the first time, scientists have calculated a detailed “energetic budget” for Hawaiʻi‘s short-finned pilot whales, revealing what it takes to power their extreme, 800-meter (2,600-feet) dives for food.

A new study led by the University of Hawaiʻi at Mānoa’s Hawaiʻi Institute of Marine Biology (HIMB) found an average adult whale must eat 142 squid daily to survive, scaling up to 416 million squid annually for the entire population of short-finned pilot whales. This data, published in the Journal of Experimental Biology, provides a new benchmark for protecting the historically understudied marine mammals.

“Pilot whales are one of the only oceanic dolphins that regularly dive to extreme depths—up to 1,000 meters—to find prey,” said William Gough, Marine Mammal Research Program (MMRP) postdoctoral researcher and lead author of the study. “This deep-diving, high-risk foraging strategy requires a delicate balance between the energy they spend and the energy they acquire. Our study is the first step in quantifying that balance for this specific population.”

Severe impact of avian flu on southern elephant seals

Elephant seals on Lagoon Island near Ryder Bay, Adelaide Island.
Photo Credit: Steve Gibbs, BAS

New research reveals 47% decline in breeding female elephant seals at sub-Antarctic island of South Georgia following a highly pathogenic avian influenza outbreak. 

Scientists from the British Antarctic Survey (BAS) have documented the severe impact of highly pathogenic avian influenza (HPAI) on southern elephant seals at South Georgia, revealing a 47% decline in breeding females between 2022 and 2024. 

The research, published today in the journal Communications Biology, shows that the world’s largest population of southern elephant seals – which accounts for over half of the global population of breeding age – has suffered unprecedented losses following the arrival of HPAI H5N1 at the remote sub-Antarctic island in late 2023. 

A system for targeted drug delivery using magnetic microrobots

Microrobots can be transported and activated in a safe and controlled manner, marking a decisive step forward in the use of these technological devices in targeted medical treatments.
Photo Credit: Courtesy of University of Barcelona

The study, led by the Swiss Federal Institute of Technology Zurich (ETH Zurich) and published in the journal Science, involves Professor Josep Puigmartí-Luis from the Faculty of Chemistry and the Institute of Theoretical and Computational Chemistry (IQTC) of the University of Barcelona. He is the only researcher from a Spanish institution to sign this paper, which is the result of the European ANGIE project, an initiative coordinated by Professor Salvador Pané (ETH) in collaboration with the Chemistry In Flow and Nanomaterials Synthesis (ChemInFlow) research group, led by Professor Puigmartí. 

The new microrobotic platform presents an innovative strategy for administering drugs in a precise and targeted manner. It is scalable and can be applied to numerous situations in which the administration of therapeutic agents is difficult to access, such as tumors, arteriovenous malformations, localized infections, or tissue injuries. 

New study finds higher hantavirus risk in drier, underdeveloped areas

A study of the long-term risk of contracting hantavirus across large geographic areas provides public health officials with information about populations most at risk for contracting hantavirus and the potential drivers of disease risk. Humans become infected with hantavirus when they inhale the airborne particles of feces and urine of disease-carrying rodents.
Photo Credit: Zoshua Colah

In a recent study of the contiguous United States, Los Alamos National Laboratory researchers found that the risk of disease from hantavirus is higher in drier, underdeveloped geographic areas with more socioeconomic vulnerability and increased numbers of unique rodent species. This is the first study to examine the combined effects of multiple variables — including socioeconomic, environmental, land use and rodent species — to determine which are most likely to predict the risk of people contracting hantavirus.

“We ran each of these variables separately — looking at where people are most at risk given just the environmental variables, just the land-use variables, etc. — and then we combined them all,” said Morgan Gorris, a scientist at Los Alamos and lead author on the study published in Transboundary and Emerging Diseases. “This gave us a map of where people are most at risk of being exposed to hantavirus and contracting hantavirus pulmonary syndrome (HPS).”

Biotechnology: In-Depth Description

Image Credit: Scientific Frontline / stock image

Biotechnology is the integration of natural sciences and engineering sciences to apply organisms, cells, parts thereof, and molecular analogues to products and services. Its primary goal is to leverage biological systems and processes to develop technologies and products that help solve problems, improve human health, enhance food production, and create more sustainable industrial and environmental processes.

Extensive dog diversity millennia before modern breeding practices

Photograph of a modern dog skull used for the photogrammetric reconstruction of 3D models in the study.
Photo Credit: C. Ameen / University of Exeter

A groundbreaking archaeological study has revealed when domestic dogs first began to show the remarkable diversity that characterizes them today. By applying cutting-edge shape analysis to hundreds of archaeological specimens spanning tens of thousands of years, researchers have traced the emergence of distinct dog forms deep into prehistory pinpointing the moment dogs began to diversify in size and shape – at least 11,000 years ago. 

These findings challenge long-standing assumptions that canine diversity is largely a recent phenomenon shaped by selective breeding which started with the Victorian Kennel Clubs. Instead, the study demonstrates that significant variation in skull shape and size among domestic dogs was already present thousands of years ago, soon after their divergence from wolves. 

Light causes atomic layers to do the twist

Fang Liu, assistant professor of chemistry in Stanford’s School of Humanities and Sciences
Photo Credit: Fawn Hallenbeck/Stanford University

A study led by Stanford and Cornell researchers shows how light could be used to control the behavior of moiré materials, atomically thin layers that gain unusual properties when stacked and offset. The research has implications for developing superconductivity, magnetism, and quantum electronics.

A pulse of light sets the tempo in the material. Atoms in a crystalline sheet just a few atoms thick begin to move—not randomly, but in a coordinated rhythm, twisting and untwisting in sync like dancers following a beat.

Until now, researchers hadn’t been able to directly observe how those layers physically respond to a burst of light. In a recent study, a team led by Stanford and Cornell University researchers showed that the atomic layers can briefly twist more tightly together, then spring back, like a coiled ribbon releasing its energy.