Feeding Ants PH

Feeding Ants PH Hello, welcome to FEEDING ANTS PH. Watch a time-lapse videos of ants eating different type of foods, while comparing it to similar product or brand.

10/10/2025

The Invasive Species That Disrupted Kenya’s Ecosystem 🇰🇪

This is not camouflage. It’s a trophy of the dead.Meet the Assassin Bug nymph — nature’s youngest warlord. But this baby...
25/05/2025

This is not camouflage. It’s a trophy of the dead.

Meet the Assassin Bug nymph — nature’s youngest warlord. But this baby doesn’t hide. It wears the fallen.

After ambushing and draining ants alive, it stacks their empty exoskeletons on its back like armor. One by one. Shell by shell. Until it’s walking beneath a moving pile of corpses.

Why? Because ants are aggressive, and smell plays everything in the insect world. By wearing dead ants, it confuses predators and masks its scent — hiding in plain death.

It doesn’t run. It doesn’t beg. It builds its shield from what it slays.

It’s not hiding. It’s declaring war.

Ants Identification Topic 11:   Hercules Carpenter Ants (Camponotus herculeanus)Camponotus herculeanus (or Hercules ant)...
22/11/2024

Ants Identification Topic 11: Hercules Carpenter Ants (Camponotus herculeanus)

Camponotus herculeanus (or Hercules ant) is a species of ant in the genus Camponotus, the carpenter ants, occurring in Northern Eurasia, from Norway to Eastern Siberia, and North America. First described as Formica herculeana by Linnaeus in 1758 the species was moved to Camponotus by Mayr in 1861.

The colony of Camponotus herculeanus consists of one or several wingless females (queens), some fertile males, and three castes of sterile workers, known as majors, intermediates, and minors, in decreasing order of size. The queens are large, about 15 mm (0.6 in) in length, and are blackish in colour. The males are a similar colour but about half the size of the queens. The workers usually have blackish heads and gasters, and dark reddish-brown mesosomas, petioles and legs. In majors, the scapes (the long segments of the antenna, before the elbow) are shorter than the length of the head; in intermediates they are about the same length, and in minors, they extend well beyond the back of the head. The head and the dorsal surfaces of the mesosoma and gaster of the largest majors are bristly.

Camponotus herculeanus has a widespread distribution in the Northern Hemisphere, being present in most of Europe, Central and Northern Asia, Canada and the United States. It is common in mountainous regions and is the dominant ant species in mountainous and northerly parts of North America. It occupies a range of habitats including various types of conifer and hardwood forests, clearings, oak scrubland, disturbed areas, pastures and seashore grassland.

Nests of Camponotus herculeanus are built in timber, living or rotting trees, stumps, fallen logs and occasionally the structural timbers of buildings. The ants use their strong jaws to excavate galleries and chambers under the bark or in the wood, with a preference for damp wood or timber with fungal decay. In standing trees, their tunnels sometimes extend for 10 m (30 ft) above the ground. Satellite colonies, linked to the original nest by underground tunnels, may develop nearby, often in warmer, drier locations. These house older larvae, pupae, winged reproductives and workers, with the eggs and younger larvae remaining in the main nest.

A colony of Camponotus herculeanus contains several wingless females, which may be unrelated. Winged reproductives are produced in late summer and overwinter in the colony, emerging to fly in swarms on warm spring days. The workers become active in spring and forage in the vicinity of the nest. They tend aphids, and the larvae of the silvery blue butterfly (Glaucopsyche lygdamus), which often feeds on the lupine Lupinus bakeri. The diet consists of the honeydew produced by sap-sucking insects and the ants also consume any insect larvae that they encounter. The ant cricket Myrmecophilus pergandei sometimes lives in the colony, where it is tolerated by the ants.

It is also one of the world’s largest ant species. The common name “Hercules ant” is not that surprising considering its size and strong jaws. Camponotus herculeanus likes to nest in both trees, rotten wood, and the walls of our homes.

Worker: Length 5-12 mm. The ant species is very dark, but the workers have a visibly reddish middle segment as well as red legs. The have many hairs and the abdomen is the body part with the most of them. They are sorted in groups and forms something that looks like eyelashes at the end of every back plate of the abdomen. It is not easy separating the Camponotus herculeanus workers from those of the close relative Camponotus ligniperda. What sets them apart though is the red area at the beginning of the abdomen. The Hercules ants have a very small red “dot” whereas the ligniperda have a much more visible red area. Just as the queen the workers have strong jaws capable of digging through hard materials such as wood.

Queen: Length 14-17 mm. The color is much darker than the workers with a black and brown shade. The sides of the body and legs have a transparent red/brown color. The hairs don’t differ much from the workers.

Male: Length 7-11 mm. Thinner body than the queens. The males are very hard to separate from the males of Camponotus ligniperda. But if you look closely you’ll see that the Camponotus herculeanus ants have a bit more and thicker hairs as well as a slightly lighter color of the wings.

The lifespan of a queen is believed to be around 10-15 years.

Camponotus herculeanus castes are strongly associated with the age of the individual ant (typical age polytheism). The young ants stay behind in the nest and tend to the brood and queens whilst their older sisters go outside to forage food, gather building materials and defend the colony from enemies.

Camponotus herculeanus is one of the really big ants of the world. At the same time it’s one of the more discrete ones as well. Even though they from time to time settle in the exterior of houses they are rarely noticed by us humans. Sadly enough it’s not unusual that their nests destroys property and in turn costs the owners a lot of money. One very interesting thing with the species is that they sometimes use sound to communicate. The workers beats on the wooden surfaces of the nest to warn the rest of the colony. The sound can travel up to 20 centimeters and makes the nearby colony members aware of a threat or otherwise.

Camponotus herculeanus is easy to keep at home. They only require a bit of patience since their development is not as quick as in other species. But instead they are big and impressive ants. Their formicarium should be of a strong material of which they cannot dig tunnels to get out. Glass, hard plastic or similar is preferred.

22/11/2024

Remastered: Soft Drinks vs Fire Ants

In this video you will find out which type of which types of soft drinks will fire ants love the most? And how long does it takes for them to consume it.

Stay tuned for more videos.










21/11/2024

This is called ant mill or ant death circle.

Ants Identification Topic 10: Bicolored Pennant Ant (Tetramorium Bicarinatum)Tetramorium bicarinatum, is a species of an...
20/11/2024

Ants Identification Topic 10: Bicolored Pennant Ant (Tetramorium Bicarinatum)

Tetramorium bicarinatum, is a species of ant of the family Formicidae in the order Hymenoptera that originated in South East Asia.

Tetramorium bicarinatum is one of the most successful, abundant, and widespread tramp species within the genus Tetramorium. It occurs in almost all tropical and subtropical habitats around the world, except for most of the Afrotropical, and also has been transferred to temperate countries where it can survive in constantly heated buildings (botanical gardens, zoos, etc.). The species is known to occur in most of the Oriental and Indo-Australian regions, including almost all Pacific island systems, the New World, Europe, the Malagasy region, and on several islands in the Atlantic and Indian Oceans (Hita Garcia and Fisher 2011). It is found in grassland and areas of bare coastal soil in Japan, where it prefers more open and dryer situations than Tetramorium nipponense. Nests are found under stones and logs.

Hita Garcia and Fisher (2011) - A member of the T. bicarinatum species complex in the Tetramorium bicarinatum species group. Tetramorium bicarinatum can be well identified within the T. bicarinatum group in the Malagasy region because of its distinctly sculptured mandibles, rectangular nodiform petiolar node with antero- and posterodorsal angles at about the same height, and its characteristic bicolouration.

The Tetramorium bicarinatum's venom arrangement shows potential for a new pharmacologically active substance, bicarinalin. This antibacterial, antimicrobial, and anti-infective compound could potentially be chemically synthesized to combat antibiotic-resistant pathogens by means of drug therapy.

The Tetramorium bicarinatum is a polygynous ant species with a colony size of up to 50,000 workers. They have a fast development rate and are around 4.2-4.6mm in size for the queen and 3-4mm for the workers. They have a reddish-brown color with variations in shades. They feed on food insects like cockroaches and crickets, as well as syrup made from water and honey.

Creating the perfect environment for your Tetramorium bicarinatum is crucial for their well-being. Maintaining the right levels of humidity and temperature is essential for their overall health and activity. In the arena, it is recommended to keep the humidity between *30-50%*, which replicates their natural habitat. For nests, a slightly higher humidity of *50-70%* is advised. In terms of temperature, the ideal range for the arena is *22-28 °C*, while nests should be kept at a slightly lower range of *20-24 °C*.

Tetramorium bicarinatum boasts several intriguing features that set them apart from other ant species. These ants are incredibly *cautious* and *secretive* in their behavior. When faced with danger, they *withdraw* rather than panic, ensuring their safety and that of their colony. Their ability to assess threats and react accordingly showcases their remarkable resilience and adaptability.

For successful breeding and keeping of Tetramorium bicarinatum, it is essential to provide them with suitable nest options. Various materials can effectively serve as nests for these ants, including *acrylic*, *cork*, *plaster*, and *aerated concrete*. These materials offer the necessary comfort and climate control to replicate their natural habitat and ensure their well-being.

Overall, Tetramorium bicarinatum ants are captivating creatures that provide a unique insight into the world of ants. With their polygyny colony type, striking coloration, diverse diet, and fascinating behavior, these ants offer endless opportunities for observation and study. By providing them with the right conditions and suitable nesting options, you can embark on an exciting journey into the captivating world of Tetramorium bicarinatum.

The highly diverse Pheidole genus of ants adapted to tropical environments twice, contributing to their success in both ...
19/11/2024

The highly diverse Pheidole genus of ants adapted to tropical environments twice, contributing to their success in both the Old and New Worlds.

AsianScientist (Jan. 4, 2015) – A study published in the Proceedings of the Royal Society Series B, suggest that Pheidole genus of ants evolved the same way twice, once to take over the New World, and then again to take over the Old World.

About one tenth of the world’s ants are close relatives; they all belong to just one genus out of 323, called Pheidole.

“If you go into any tropical forest and take a stroll, you will step on one of these ants,” says Okinawa Institute of Science and Technology Graduate University’s (OIST) Professor Evan Economo.

Pheidole fill niches in ecosystems ranging from rainforests to deserts. Yet until now, researchers have never had a global perspective of how the many species of Pheidole evolved and spread across the Earth.

Economo, researchers in the Biodiversity and Biocomplexity Unit, and colleagues at the University of Michigan compared gene sequences from 300 species of Pheidole from around the world. They used these sequences to construct a tree that shows when and where each species evolved into new species. At the same time, in a parallel effort, they scoured the academic literature, museums around the world, and large databases to aggregate data on where all 1,200 or so Pheidole species live on Earth, creating a range map for each species.

Economo began this project by selecting sample ants to represent each Pheidole species. The team then sequenced the samples’ DNA to determine genetic similarities between species, and computationally reconstruct the “family tree” of Pheidole species, providing a history of how they evolved. This may seem like a lot of effort for a group of seemingly inconsequential creatures, but in fact many ecologists use ants to better understand evolution and the terrestrial ecosystems ants inhabit.

“Ants are a good test case,” said Economo.

Ants are abundant in most terrestrial ecosystems, often accounting for as much biomass as all vertebrates combined. They serve important roles such as soil aeration, nutrient cycling, and dispersing plant seeds. They also have economic consequences for humans; certain ant species become pests and cause billions of dollars of damage.

In addition, their social behavior interests many researchers, so even if they are not as well studied as mammals or birds, there is a relatively large library of research compared to other arthropods. Because of their global ubiquity, Pheidole ants in particular offer ecologists a view into a wide range of ecosystems.

Economo compared the Pheidole evolutionary tree with the range map showing where each Pheidole species lives. One might think that with hundreds of species living on almost every continent, there have been lots of movements and colonizations around the world. But if that were the case, Economo would find species that are close relatives living in different continents. Instead, Economo found that the genus was split into two main groups of evolutionary relatives: one in the New World, or the Americas, and one in the Old World, or Europe, Asia, Africa, and Australia.

“The new world and the old world are almost completely independent of each other,” Economo said. “Pheidole first evolved in the new world, from one species to over six hundred species.” Then, one of those ants colonized the old world, where it evolved into another six hundred or so ant species.”

Pheidole species also show a climate pattern: there tend to be more Pheidole in warm, wet climates.

“They are dominant in certain areas preferentially to others,” Economo said, “and these patterns are consistent even though they evolved independently.”

This suggests that evolution repeated itself, and is to some extent deterministic. That is, there is likely a reason why Pheidole dominate tropical ecosystems: they didn’t just become successful due to random chance.

Moving forward, Economo hopes to learn how so many Pheidole species can coexist by studying how they forage for food, nest, and otherwise thrive in their local environments. Knowing these habits would help understand whether Pheidole is the best at surviving, or whether its environment can simply support more ant species.

“That’s a big question for our field in general,” Economo said, “not just in ants.”

This paper constitutes a significant step forward toward understanding ant biodiversity.

“This is an extremely difficult genus to work with because they are so diverse and hard to identify” Economo said, “so hopefully our work will help scientists get a better handle on these organisms that are dominant features of many of Earth’s ecosystems.”

FROM: ASIAN SCIENTIST

Ants Identification Topic 9: Spotted Sugar Ants (Camponotus Maculatus)Camponotus maculatus is a monogynous ant species w...
18/11/2024

Ants Identification Topic 9: Spotted Sugar Ants (Camponotus Maculatus)

Camponotus maculatus is a monogynous ant species with colonies of up to 10,000 workers. They have a fast development speed. The queen measures 15-17mm, workers measure 6-10mm, and majors measure 13-16mm. The ants have a black head and unevenly colored breast and belly. They are fed on food insects and syrup.

Camponotus maculatus, also known as the spotted carpenter ant, is a highly active species of ant that is recognized for its active behavior outside the nest and during foraging. Native to, this species stands out with its characteristic spotted pattern on the abdomen.

Well known, common and widely distributed throughout Africa. A common ground nesting and foraging ant which often ascends trees to tend aphids, but does not build tents (Taylor 1977). It was not among the commoner species in the 76-farm survey of Taylor & Adedoyin (1978). Known to be prey of Oecophylla longinoda (Taylor et al., 2018). While this species has been suggested as being invasive in may parts of the world, these reports appear to be largely the result of misidentifications or are presented with little or no justification; additional details are required to confirm its occurrence outside its native range.

A common ground nesting and foraging ant which often ascends trees to tend aphids, but does not build tents.

Dung beetles navigate to a safe place to eat their takeout, but bull ants actually use polarized light to make their way...
17/11/2024

Dung beetles navigate to a safe place to eat their takeout, but bull ants actually use polarized light to make their way to a specific location.

Australian bull ants (Myrmecia midas, shown) forage for tree sap and other resources at night, and new research suggests that they use polarized moonlight to find their way back home.

As the sun goes down outside of Sydney, Australia, bull ants march out of their nests and into the trees.

Once there, the ants attack other insects and arthropods, as well as collect tree sap and other resources, before returning to the nest with their haul before dawn.

However, unlike many other ant species, which follow the scent trails left by their sisters, bull ants of the species Myrmecia midas don’t appear to communicate by chemical signal. Instead, each forager forges its own path.

And that raises an interesting question: How do nocturnal bull ants find their way home in the dark?

“It’s always kind of been this mystery,” says Cody Freas, a neuroethologist at Macquarie University in Australia.

Fortunately, a new study appears to shine some light on this enigma: Bull ants use the moon’s polarized light like a nocturnal compass, the scientists conclude.

While human eyes are attuned to certain wavelengths of light emitted by the sun and stars or reflected from the moon, the top-most part of bull ants’ eyes can see a pattern in the sky that’s invisible to us—polarized light. This pattern shines through even when celestial bodies are obscured by clouds.

By manipulating the pattern with a filter placed over the ants as they returned to nests in the wild, the scientists were able to show that the insects were following that signal and making course-corrections based on it in real-time, as opposed to navigating based on a memory of its position.

The filter “basically changes the entire sky above them,” explains Freas, who was lead author of the study, recently published as a reviewed preprint in the journal eLife.

The ants showed themselves capable of navigating by polarized moonlight even during a crescent moon, when the light signal would have been just 20 percent as strong as a full moon—which itself provides light one million times weaker than direct sunlight.

While dung beetles are known to use polarized light from the moon and even stars to keep their balls rolling in a straight line, this is the first time an animal has been shown to navigate by polarized moonlight toward a fixed location—the bull ants’ home.

While the study is the first to document the ants’ use of polarized light for nocturnal navigation, the scientists have had a hunch for awhile now that the moon was involved.

“A big hint that the moon was kind of at play is that you see a 20 percent increase in foragers when the moon is full, versus a new moon [when the sky is much darker],” says Freas, referring to an earlier study of closely-related M. pyriformis ants.

This suggested that bull ants could see better when moonlight was stronger.

Interestingly, despite traveling up to 78 feet along the ground in the dark, Freas says nearly every ant makes it back to the nest. In fact, in all his observations of bull ants, he’s only noticed a single ant go missing.

“They live for over a year, and they typically go to the same tree every night. So it’s not a new route every night,” says Freas. “So that suggests, at least to me, that they’re really good at getting home. There’s very little getting lost, and there’s also very little overnight predation.”

Bull ants are considered quite feisty, especially when disturbed by humans, which may also deter other predators. Freas says the largest bull ants can be more than an inch long, and capable of stinging curious scientists through their gloves. (He knows from experience, by the way.)

“If you’re moving around while you’re near the nest, they will home in on your movement and continue to go after you for multiple meters,” he says.

Since researchers previously discovered that dung beetles navigate by polarized light at night, finding the same ability in another insect isn’t too surprising. In fact, it’s likely still more insects are navigating by these cues, unbeknownst to us.

The catch is, you need a good behavior that allows you to test for it, says James Foster, a neuroethologist at the University of Konstanz in Germany who studies dung beetles.

For instance, when dung beetles collect their little ball of animal f***s, they try to roll it away from competitors as quickly and efficiently as possible. Usually, that means a straight line.

Similarly, bull ants returning home from a night of foraging is a repeatable behavior that allowed the scientists to test their theories upon, he says. But there is a big difference between the two animals.

Dung beetles “don’t have to find any specific location,” says Foster who reviewed the study during the publication process. “Whereas for these ants, they have to find their way home quite precisely.” That makes the bull ants’ feat even more impressive.

The other big difference? Dung beetles don’t sting.

“I can’t imagine how difficult these experiments were to do, chasing ants around in the dark,” says Foster.

FROM: NATIONAL GEOGRAPHIC










Address

Manila
4103

Alerts

Be the first to know and let us send you an email when Feeding Ants PH posts news and promotions. Your email address will not be used for any other purpose, and you can unsubscribe at any time.

Share