Tag Archives: microscopic

Microscopic Images Unveil the Remarkable Complexity of the Tiny World

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Michael Benson’s photograph of an insect fly, with the flower and fly measuring just over 1 cm in diameter.

© 2025 Michael Benson

Inside a drawstring bag, you’ll find equipment like bug nets, tweezers, and small plastic vials. This may seem unusual for a photographer, but for Michael Benson, it’s just part of his routine. He dedicated over six years to gathering specimens for his latest publication, Nanocosmos: A Journey Through Electronic Space, a collection showcasing the microscopic realm in exquisite detail.

“I’m fascinated by the boundary between known and unknown territories—an area often linked to science,” he shares. “However, I approach it as an artist, not a scientist.”

That didn’t deter Benson from utilizing tools typically reserved for physicists and biologists. He produced all images for Nanocosmos using a formidable scanning electron microscope (SEM). This advanced technique employs a highly focused electron beam to intricately map surface contours. The resulting images portray submillimeter objects with such clarity that they appear almost extraterrestrial.

Take, for instance, the Acilidae musbifolia (as seen in the main image) alongside a flowering plant in Alberta, Canada. Even together, they span only slightly more than 1 cm. But with SEM technology, we can observe nearly every hair on the fly’s body, each claw on its legs, and even some of the countless individual receptors forming its bulging eyes.

Benson first utilized SEM in 2013 at the Massachusetts Institute of Technology’s Media Lab. “Learning to master SEM was challenging, requiring several years of practice,” he notes. Every specimen must be coated with “a molecularly thin layer of platinum to prevent charging by the electron beam,” and meticulously dried to maintain surface details.


Wing of the Erythemis simplicicollis dragonfly, approximately 3 mm wide, seen from the tip.

© 2025 Michael Benson

The image above showcases the wing feathers of the eastern pontaka dragonfly (Erythemis simplicicollis), captured from beneath at the wing tip. This species is found across the eastern two-thirds of the United States, as well as in southern Ontario and Quebec, Canada. The wings are about 3 mm wide.

Below are images of single-celled marine organisms, specifically Hexalonche philosophica, collected from the equatorial region of the Pacific Ocean, measuring just 0.2 millimeters from tip to tip.

Marine organism Hexalonche philosophica, about 0.2 mm in length

© 2025 Michael Benson

Another marine specimen, Ornithocercus magnificus (featured below), is a type of plankton discovered in the Gulf Stream off Florida’s coast, measuring approximately 0.1 mm in width.

Ornithocercus magnificus, with a width of about 0.1 mm.

© 2025 Michael Benson

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Source: www.newscientist.com

The World’s Hottest Engine Unveils the Mysteries of Microscopic Physics

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Extreme Engine Artist Representation

Milen Lab

The world’s most advanced engines are remarkably compact, achieving astonishing levels of efficiency, mirroring some of nature’s tiniest machines.

A thermodynamic engine represents the most straightforward mechanism to illustrate how the laws of physics govern the conversion of heat into useful work. These engines feature areas of heat and cold interconnected by a “working fluid” that goes through cycles of contraction and expansion. Molly’s Message and James Mirren from King’s College London and their team have constructed one of the most extreme engines yet, utilizing microscopic glass beads in place of traditional working fluids.

The researchers employed electric fields to trap and position the beads in diminutive chambers crafted from metal and glass with minimal air. To operate the engine, they varied the electric field parameters to tighten and loosen the beads’ “grip.” A handful of air particles within the chamber acted as the cold section of the engine, while manipulated spikes in the electric field represented the hot section. These spikes enabled the particles to move significantly faster than the sparse air particles in their vicinity. Notably, the glass particles experienced speeds greater than what they could achieve in gas while remaining cool to the touch, despite their temperature briefly spiking to 10 million Kelvin—approximately 2,000 times the sun’s surface temperature.

This glass bead engine functioned in an atypical manner. During certain cycles, it displayed striking efficiency, as the strength of the electric field propelled the glass beads at unexpected speeds, effectively generating more energy than was inputted. However, in other cycles, the efficiency dropped to negative levels, as if the beads were being cooled in scenarios where they should have heated further. “At times, you believe you’re inputting the correct energy. You’re attempting to run the fridge with the appropriate mechanisms designed to operate the heat engine,” explains Message. The temperature of the beads fluctuated based on their location within the chamber, an unexpected outcome given that the engine was designed to maintain specific hot or cold sections.

These peculiarities can be attributed to the engine’s minuscule size. Even a single air particle colliding randomly with the beads can drastically impact the engine’s performance. Although traditional physical laws generally prevail, sporadic extreme phenomena persist. Mirren notes that a similar situation exists for the microscopic components of cells. “You can observe all these strange thermodynamic behaviors, which make sense on a bacterial or protein level, but are counterintuitive for larger entities like ourselves,” he states.

Raul Rika from the University of Granada in Spain mentions that while this new engine lacks immediate practical applications, it may deepen researchers’ understanding of natural and biological systems. It also signifies a technical breakthrough. Loïc Rondin from Paris’ Clay University asserts that the team can further investigate numerous unusual characteristics of the microscopic realm with this relatively straightforward design.

“We are significantly simplifying what will become a biological system ideal for testing various theories,” states Rondin. The team aspires to apply the engine in the future for tasks such as modeling how protein energy varies during folding.

Journal Reference: Physical Review Letters, In print

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Source: www.newscientist.com

Possible Origins of Life on Earth: Peculiar Microscopic Lightning Effects

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Exploring the origins of life is a profound scientific question. While evolution explains how life changes over time, the initial creation of the first biological structures remains a mystery.

In order for life to appear, the Earth required specific molecules containing carbon and nitrogen. However, these essential compounds were absent for millions of years after the planet’s formation. Recent research suggests a potential source for these crucial molecules.

This study proposes that microlites, small bursts of electricity generated when a water droplet breaks, played a key role in the formation of these compounds. These energy bursts are a common occurrence in nature, from ocean waves crashing against the shore to waterfalls spraying mist.

Research indicates that these intense energy releases may have triggered a chemical reaction that produced the fundamental components necessary for life to begin.

Professor Richard Zare, a co-author of the research published in Advances in Science, explains the importance of carbon-nitrogen bonds in creating amino acids and nucleic acids, the building blocks of proteins and DNA.

While previous theories, like the Miller-Urey hypothesis, suggested that lightning strikes into the ocean could have jump-started the chemistry of life, criticisms have been raised about the feasibility of this scenario. New research proposes that the building blocks of life may have been formed over time through numerous small electrical discharges worldwide.

The discovery of microlites producing organic molecules from simple components has broader implications beyond the origins of life. This research suggests that these small electrical discharges could play a significant role in various natural chemical processes.

Dr. Zare emphasizes the importance of studying the chemistry of small water droplets, highlighting the potential for groundbreaking discoveries in this area. This study demonstrates how seemingly insignificant everyday processes may hold the key to profound mysteries, such as the origins of life.

About our experts

Richard Zare is a distinguished chemist and professor at Stanford University, with numerous publications in prestigious journals and multiple awards for his research and educational contributions.

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Source: www.sciencefocus.com