Those who knows ☠️....#trollface

Explanation: this is church but not for christian bro this is a cursed church that was found and its forbidden to get in there💀 many people died there but if thats true i dont know

Paper-ng

Explanation:Basically there were a lot of people that went to this church. A lot of the people that went to this church Sinned. Then one day when everyone went to this church at night the priest died out of no where then everyone stayed inside because they were scared of the sacred ghosts that haunted them. Eventually they all died inside this church and now weird sounds come from there. This place eventually got banned because of the amount of deaths that occur when people visit this church. There are rumours that this church could be a porthole to a different world that were not supposed to know about. I hope this helps.

sammajikija

Church was abandoned because the priest died out of nowhere nothing happened and all the people also died☠️...

clashgamer

my dumb brain thought it was Franklin's house from gta

_dj_

My dumbass thought it was Plants vs Zombies in real life

Ultimaters

As a Muslim i can confirm this is an absolute win (cuz i ain't cooked)
Edit: Bruh now y'all making a war cuz of religions

JurassicEdts

Explanation: it was the mysterious turkish jelqer

BayHarbourUrinalMan

Explanation:

Grass is one of the three basic elemental types along with Fire and Water, which constitute the three starter Pokémon. This creates a simple triangle to explain the type concept easily to new players.
Grass is one of the weakest types statistically, with 5 defensive weaknesses and 7 types that are resistant to Grass moves. Furthermore, three type combos paired with Grass have 7 weaknesses: Grass/Psychic, Grass/Ice, and Grass/Dark.
cladeFamily:Poaceae
Barnhart[2]Type genusPoa

L.

Subfamilies

Anomochlooideae

Aristidoideae

Arundinoideae

Bambusoideae

Chloridoideae

Danthonioideae

Ehrhartoideae

Micrairoideae

Panicoideae

Pharoideae

Pooideae

Puelioideae

Synonyms[3]
Gramineae Juss.
With around 780 genera and around 12, 000 species, [4] the Poaceae is the fifth-largest plant family, following the Asteraceae,  Orchidaceae,  Fabaceae and Rubiaceae.[5]
The Poaceae are the most economically important plant family, providing staple foods from domesticated cereal crops such as maize,  wheat,  rice,  oats,  barley, and millet for people and as feed for meat-producing animals. They provide, through direct human consumption, just over one-half (51%) of all dietary energy; rice provides 20%, [6] wheat supplies 20%, maize (corn) 5.5%, and other grains 6%.[citation needed] Some members of the Poaceae are used as building materials (bamboo,  thatch, and straw); others can provide a source of biofuel, primarily via the conversion of maize to ethanol.
Grasses have stems that are hollow except at the nodes and narrow alternate leaves borne in two ranks. The lower part of each leaf encloses the stem, forming a leaf-sheath. The leaf grows from the base of the blade, an adaptation allowing it to cope with frequent grazing.
Grasslands such as savannah and prairie where grasses are dominant are estimated to constitute 40.5% of the land area of the Earth, are also an important part of the vegetation in many other habitats, including wetlands,  forests and tundra.
Though they are commonly called "grasses", groups such as the seagrasses,  rushes and sedges fall outside this family. The rushes and sedges are related to the Poaceae, being members of the order Poales, but the seagrasses are members of the order Alismatales. However, all of them belong to the monocot group of plants.
Grass type Pokémon are immune to powder and spore moves - Cotton Spore,  Leech Seed,  Poison Powder,  Powder,  Rage Powder,  Sleep Powder,  Spore and Stun Spore - as well as the ability Effect Spore.

The power of Grass type moves increases by 30% when Grassy Terrain is active.

The Overgrow ability increases the power of Grass type moves by 50% when the Pokémon has less than 1⁄3 HP remaining.

The ability Sap Sipper raises the Pokémon's Attack one stage when hit by a Grass type attack, instead of dealing damage.

The ability Flower Veil prevents the stats of ally Grass type Pokémon from being lowered.

The move Flower Shield raises the Defense of all Grass type Pokémon one the field by one stage; Rototiller does the same for both Attack and Special Attack.

The move Forest's Curse adds the Grass type to the target's type.

The items Meadow Plate,  Miracle Seed and Rose Incense increase the power of Grass type moves by 20% when held.

The Grass Gem increases the power of a Grass type move by 30% when held, and is then consumed.

The Rindo Berry, when held, neutralizes a super-effective Grass type move.

A common kind of grass is used to cover the ground in places such as lawns and parks. Grass is usually the color green. That is because they are wind-pollinated rather than insect-pollinated, so they do not have to attract insects. Green is the best colour for photosynthesis.
Grasslands such as savannah and prairie are where grasses are dominant. They cover 40.5% of the land area of the Earth, but
Grasses are monocotyledon herbaceous plants. They include the "grass" of the family Poaceae, which are called grass by ordinary people. This family is also called the Gramineae and includes some of the sedges (Cyperaceae) and three families are not very closely related, though all of them belong to clades in the order Poales. They are similar adaptations to a similar life-style.
With about 780 genera and about 12, 000 species, [3] the Poaceae is the fifth-largest plant family. Only the Asteraceae,  Orchidaceae,  Fabaceae and Rubiaceae have more species.[6]
The true grasses include cereals,  bamboo and the grasses of lawns (turf) and grassland. Uses for graminoids include food (as grain,  shoots or rhizomes), drink (beer,  whisky),  pasture for livestock,  thatch,  paper,  fuel,  clothing,  insulation,  construction,  basket weaving and many others.
Many grasses are short, but some grasses can grow tall, such as bamboo. Plants from the grass family can grow in many places and make grasslands, including areas which are very dry or cold. There are several other plants that look similar to grass and are referred to as such but are not members of the grass family. These plants include rushes,  reeds,  papyrus and water chestnut. Seagrass is a monocot in the order Alismatales.
Grasses are an important food for many animals, such as deer,  buffalo,  cattle,  mice,  grasshoppers,  caterpillars and many other grazers. Unlike other plants, grasses grow from the bottom, so when animals eat grass, they usually do not destroy the part that grows.[7] This is part of the reason why the plants are so successful.

punianitui

For those who don’t know


Nuclear fission is a fundamental process in nuclear physics and energy production, playing a key role in both scientific research and power generation. It involves the splitting of a heavy atomic nucleus into two or more lighter nuclei, releasing a significant amount of energy in the form of heat and radiation. This process is harnessed in nuclear reactors to generate electricity and has applications in various fields, ranging from medicine to national defense. The discovery and development of nuclear fission have transformed the world, both in terms of energy capabilities and the associated ethical and safety concerns.


At the core of nuclear fission lies the interaction between a heavy atomic nucleus, such as uranium-235 or plutonium-239, and a neutron. When a neutron collides with the nucleus of an atom, it can be absorbed, making the nucleus unstable. This instability causes the nucleus to split into two smaller nuclei, known as fission fragments. Along with the fission fragments, a few neutrons are also released, which can then initiate additional fission reactions in a chain reaction.

The energy released in nuclear fission comes from the conversion of a small portion of the mass of the nucleus into energy, in accordance with Einstein’s famous equation, E = mc^2. This energy is primarily in the form of kinetic energy of the fission fragments and the released neutrons, as well as the energy from gamma radiation emitted during the process.

A crucial aspect of nuclear fission is the chain reaction. As fission produces more neutrons, these can go on to split other nuclei, leading to a self-sustaining process. This chain reaction is the basis of how nuclear reactors operate. In reactors, the chain reaction is carefully controlled using materials such as control rods, which absorb neutrons and prevent the reaction from escalating uncontrollably.


One of the most prominent uses of nuclear fission is in the generation of nuclear power. In nuclear power plants, controlled fission reactions take place within a reactor to produce heat. This heat is used to generate steam, which drives turbines connected to electricity generators. Nuclear power provides a significant portion of the world’s energy, offering a low-carbon alternative to fossil fuels and contributing to efforts to combat climate change.

In addition to electricity generation, nuclear fission is used in the production of medical isotopes, which are essential for medical imaging and cancer treatment. The controlled use of fission allows for the creation of isotopes like iodine-131 and cobalt-60, which are used in diagnostic imaging and radiation therapy, respectively.

Another application of nuclear fission is in the military domain. The destructive potential of uncontrolled fission reactions was first demonstrated during World War II with the development of nuclear weapons, most notably the atomic bombs dropped on Hiroshima and Nagasaki in 1945. These weapons harness the immense energy released from a rapid chain reaction, resulting in a devastating explosion and long-lasting effects due to radiation.


The primary advantage of nuclear fission is its ability to produce large amounts of energy from a relatively small amount of fuel. A small quantity of uranium-235 or plutonium-239 can generate immense amounts of energy, making it highly efficient compared to traditional fossil fuels like coal or oil. Additionally, nuclear power produces minimal greenhouse gas emissions, making it an important tool in reducing the impact of climate change.

However, the use of nuclear fission comes with significant challenges and risks. One of the most pressing concerns is the management of nuclear waste. Fission produces radioactive byproducts, some of which remain hazardous for thousands of years. Safe disposal and long-term storage of nuclear waste are critical issues that have yet to be fully resolved.

Another major concern is the potential for nuclear accidents. High-profile disasters such as the Chernobyl disaster in 1986 and the Fukushima Daiichi disaster in 2011 have raised serious concerns about the safety of nuclear power plants. While modern reactors are designed with advanced safety features, the possibility of a catastrophic failure or meltdown still poses a risk, especially in the event of natural disasters, human error, or malicious attacks.

Additionally, the proliferation of nuclear technology raises the issue of nuclear weapons development. The same technology used for peaceful nuclear energy can be adapted for military purposes, leading to global security concerns. International efforts to regulate and control the spread of nuclear materials, such as the Treaty on the Non-Proliferation of Nuclear Weapons (NPT), aim to mitigate these risks.


Nuclear fission is a powerful and transformative process that has shaped modern society in numerous ways. From its pivotal role in energy production to its medical applications, nuclear fission has brought about significant advances. However, its potential for harm, as demonstrated by nuclear accidents and the threat of nuclear weapons, highlights the need for careful regulation, safety protocols, and ethical considerations. As the world continues to seek sustainable energy solutions, the future of nuclear fission will likely remain an important area of focus, balancing its remarkable potential with the inherent risks it poses.

Pilotcornilius

I thought it was Saddam Husseins hiding spot when he ran way.

Aryanfamous

Bro found a cursed church☠️☠️☠️😈
Edit: DAYUM THANKS FIR 1.5K LIKES ITS THE MOST IV EVER GOTTEN❤❤❤
Edit 2: thanks for 2.2k likes

Nate_the_Great

Explicação: esta é uma igreja, mas não para cristãos, mano, esta é uma igreja amaldiçoada que foi encontrada e é proibido entrar lá, muitas pessoas morreram lá, mas se isso for verdade, eu não sei. Editar: Droga, acabei de acordar e tantos likes??? Wtff, tysm, isso é o máximo que eu consegui

IsabelSilva-cb

For those who don’t know

The **A-10 Thunderbolt II**, often called the "Warthog" or simply the "Hog, " is an iconic ground attack aircraft used by the United States Air Force (USAF) and designed primarily for close air support (CAS) of ground troops. Its distinctive appearance and powerful capabilities make it one of the most recognized military aircraft in the world.

### Design and Features
The A-10 was designed by *Fairchild Republic* in the 1970s with the primary goal of providing support to ground forces, especially in the event of a large-scale ground conflict like a potential war in Europe during the Cold War. The aircraft has a rugged, utilitarian design, built to withstand the challenges of low-altitude, close-range combat operations. This design prioritizes survivability, maneuverability, and firepower, even in hostile environments.

*One of the most distinctive features* of the A-10 is its **large, straight wings**, which provide excellent lift at slower speeds, making the aircraft highly effective for operations in congested or dangerous environments. The wings are also designed with a high degree of maneuverability, allowing the Warthog to fly low and slow while maintaining effective weapon accuracy, even in challenging terrain.

Another key feature is the **cockpit**. The A-10 has a cockpit that is heavily armored, designed to protect the pilot even in the event of taking direct hits from small arms fire or surface-to-air missiles. The seat is mounted on an ejection seat that is specifically designed for high-speed ejections, ensuring the pilot’s safety even during extreme situations.

The aircraft's *cockpit canopy* is made from bulletproof glass, designed to provide excellent visibility for the pilot while protecting them from fire. The A-10’s *nose section* features a unique **muzzle brake**, which enhances the stability of the aircraft and reduces recoil from the powerful gun mounted on the nose.

### The Gun
One of the defining characteristics of the A-10 is its *GAU-8/A Avenger rotary cannon**, which is arguably the most powerful aircraft gun in service. The GAU-8/A is capable of firing **30mm rounds at a rate of 3, 900 rounds per minute**, which is devastating when it comes to destroying tanks, armored vehicles, and other ground targets. The sheer firepower and precision of the A-10’s cannon make it an exceptional close support weapon. It has a **5, 000-pound payload* of ammunition, allowing it to engage a variety of ground targets, including enemy infantry, fortifications, and vehicles.

The cannon is mounted in the aircraft's nose, positioned directly in front of the pilot for optimal targeting accuracy. The positioning allows the Warthog to effectively strafe the ground in low-altitude passes, providing continuous fire while maintaining a direct line of sight. The powerful recoil of the cannon is offset by a specially designed muzzle brake, which reduces the stress on the airframe and ensures the aircraft remains stable when firing.

### Durability and Survivability
The A-10’s design places a heavy emphasis on survivability, ensuring that the aircraft can continue operating even when damaged by enemy fire. The aircraft is **built with a titanium "bathtub" around the pilot**, providing a protective shell in the event of a hit. This titanium armor is designed to withstand fire from small arms and even some types of cannon fire. The A-10 can continue to fly even if it takes substantial damage, such as losing an engine, a wing, or having parts of the fuselage or tail section destroyed. This durability is a critical aspect of its role in close air support, as it often operates in hostile environments where damage is likely.

Moreover, the A-10’s *wings are designed to be highly resilient**, with the ability to continue flying even if they are severely damaged. The aircraft’s engines are mounted high above the fuselage, reducing the likelihood of them being struck by ground fire. Additionally, the A-10 features **redundant flight systems* that ensure the aircraft remains controllable even if some systems are damaged.

### Engine and Performance
The A-10 is powered by two *TF34-GE-100 turbofan engines**, which are designed for reliability and simplicity. These engines are capable of producing **9, 065 pounds of thrust* each, which allows the Warthog to cruise at speeds up to **450 miles per hour (724 km/h)**. While not the fastest aircraft, the A-10's ability to fly slowly and stay on target for extended periods is crucial for close support operations. This relatively low speed allows the pilot to fly below radar detection and remain in close proximity to ground units.

The engines are mounted on pods located above the fuselage, which helps protect them from ground fire and keeps them out of the immediate danger zone during close air support missions. Additionally, the engines are mounted with *high-mounted inlets* that allow the A-10 to operate from austere airstrips or forward operating bases with minimal infrastructure, a key advantage in combat situations.

### Versatility in Combat
The A-10 is specifically designed for close air support missions, but it is a highly versatile platform capable of engaging a wide range of targets. It can be equipped with a variety of weapons systems, including *precision-guided munitions (PGMs)* like laser-guided bombs, rockets, and missiles. This flexibility allows the A-10 to operate in a variety of combat scenarios, including anti-tank operations, troop support, interdiction missions, and close-quarters combat.

The aircraft's *weapon systems are mounted externally on under-wing pylons**, which can carry a combination of bombs, rockets, and missiles, as well as fuel tanks for extended range. The A-10 also features **advanced targeting systems* such as a targeting pod that helps the pilot to lock onto specific targets, making the aircraft more effective in precision strikes.

### Role in Modern Warfare
Since its introduction in 1977, the A-10 has played a significant role in numerous conflicts, including the Gulf War, the War in Iraq, and the War in Afghanistan. In each of these conflicts, the A-10 has proven to be a valuable asset, providing close support to ground troops and engaging enemy armor, artillery, and infantry with its formidable cannon and precision munitions.

One of the defining aspects of the A-10’s role is its ability to perform close support missions in complex, contested environments. It operates effectively in both day and night missions, in both clear and adverse weather conditions, ensuring that ground forces receive effective air support whenever needed. Its ability to loiter over a battlefield for extended periods makes it an invaluable resource for commanders on the ground.

### Legacy and Future
As the A-10 reaches the latter stages of its service life, there have been ongoing debates within the U.S. Air Force about its future. Despite this, the Warthog continues to be a beloved aircraft among those who serve with it. Its unique design and proven effectiveness have cemented its place in military history. The A-10 has been so successful in its role that it has survived repeated attempts to retire or replace it, with many lawmakers, airmen, and soldiers lobbying for its continued service.

In recent years, discussions have centered around the **A-10’s replacement**, with some advocating for newer aircraft, such as the **F-35 Lightning II**. However, despite the growing role of more advanced multi-role fighters, the A-10 remains unmatched in its specific close air support mission, with its combination of durability, firepower, and low-speed capabilities proving difficult to replicate in newer platforms.

In response to these debates, the Air Force has invested in upgrades and modifications to extend the life of the A-10, including avionics upgrades, weapons system improvements, and structural reinforcements. Additionally, modern versions of the A-10 have been equipped with more advanced targeting systems and data-link capabilities, ensuring that it remains a valuable asset for current and future conflicts.

### Conclusion
The A-10 Thunderbolt II, or "Warthog, " is a symbol of unmatched ruggedness, firepower, and versatility in close air support missions. With its *distinctive appearance, powerful gun, and ability to keep flying even under extreme damage**, it remains a unique and highly effective platform. Despite the emergence of new aircraft technologies, the A-10's **legacy* as the ultimate close air support aircraft continues to endure, making it an irreplaceable asset in modern military operations.

recspooky

For those who ask for this funk name it is : toma pipocada

ChamnanRaing

My dumbass thought it was choo choo charles irl

SuperPlaza

EXCEPT: This is a church not only for Christian: its about in 2001 July 2 some man defined because of spirits and I have been : as in the bible ; and it's a cursed chruch;

jandiipogi

Nice edit when every i search troll there's come ur video first💀 pin me

zayaanandabubakar

As a true Muslim I ain't cooked even if I live there

amirameskini

Jesus Is Lord. Accept him before his return

itzrukky

For those who don't know



The immense destructive power of atomic weapons derives from a sudden release of energy produced by splitting the nuclei of the fissile elements making up the bombs’ core. The U.S. developed two types of atomic bombs during the Second World War. The first, Little Boy, was a gun-type weapon with a uranium core. Little Boy was dropped on Hiroshima. The second weapon, dropped on Nagasaki, was called Fat Man and was an implosion-type device with a plutonium core.
Fission
The isotopes uranium-235 and plutonium-239 were selected by the atomic scientists because they readily undergo fission. Fission occurs when a neutron strikes the nucleus of either isotope, splitting the nucleus into fragments and releasing a tremendous amount of energy. The fission process becomes self-sustaining as neutrons produced by the splitting of atom strike nearby nuclei and produce more fission. This is known as a chain reaction and is what causes an atomic explosion.
When a uranium-235 atom absorbs a neutron and fissions into two new atoms, it releases three new neutrons and some binding energy. Two neutrons do not continue the reaction because they are lost or absorbed by a uranium-238 atom. However, one neutron does collide with an atom of uranium-235, which then fissions and releases two neutrons and some binding energy. Both of those neutrons collide with uranium-235 atoms, each of which fission and release between one and three neutrons, and so on. This causes a nuclear chain reaction. For more on this topic, see Nuclear Fission.
Criticality
In order to detonate an atomic weapon, you need a critical mass of fissionable material. This means you need enough U-235 or Pu-239 to ensure that neutrons released by fission will strike another nucleus, thus producing a chain reaction. The more fissionable material you have, the greater the odds that such an event will occur. Critical mass is defined as the amount of material at which a neutron produced by a fission process will, on average, create another fission event.
The Difference Between the Bombs
Little Boy and Fat Man utilized different elements and completely separate methods of construction in order to function as nuclear weapons. Little Boy detonated due to a fission chain reaction involving the isotope U-235 of uranium, while Fat Man used plutonium’s Pu-239 form.
Little Boy was powered by the uranium isotope U-235 in a process that didn’t come easily to the many Manhattan Project scientists working on the uranium extraction and enrichment process. Most uranium found naturally in the world exists as uranium-238, leaving only 0.7% of naturally existing uranium as the U-235 isotope. When a neutron bombards U-238, the isotope often captures the neutron to become U-239, failing to fission, and thus failing to instigate a chain reaction that would detonate a bomb. The first challenge of the project was thus to determine the most efficient way to separate and purify uranium-235 from the overly-abundant uranium-238 – standard methods of separation could not be used due to the strong chemical similarity between the two isotopes. In order to avoid wasting time on one new method that could later prove insufficient to produce enough U-235 to allow the atomic bomb to reach critical mass, General Leslie Groves consulted with lead scientists of the project and agreed to investigate simultaneously four separate methods of separating and purifying the uranium-235: gaseous diffusion, centrifuge, electromagnetic separation and liquid thermal diffusion.
Once enough U-235 was obtained to power the bomb, Little Boy was constructed using a gun-type design that fired one amount of U-235 at another to combine the two masses. This combination created a critical mass that set off a fission chain reaction to eventually detonate the bomb. The two masses of U-235 had to combine with one another quickly enough to avoid the spontaneous fission of the atoms, which would cause the bomb to fizzle, and thus fail to explode.
Fat Man
Powered by plutonium, Fat Man could not use the same gun-type design that allowed Little Boy to explode effectively – the form of plutonium collected from the nuclear reactors at Hanford, WA for the bomb would not allow for this strategy. The Hanford plutonium emerged from the reactors less pure than the initial plutonium extracted from Ernest O. Lawrence’s Berkeley Lab, instead containing traces of isotope plutonium-240, as opposed to the desired plutonium-239. Plutonium-240’s higher fission rate would cause the atoms to undergo spontaneous fission before the gun-type design could bring two masses of plutonium together, which would lower the energy involved in the actual detonation of the bomb.
Thus, a new design was required. Physicist Seth Neddermeyer at Los Alamos constructed a design for the plutonium bomb that used conventional explosives around a central plutonium mass to quickly squeeze and consolidate the plutonium, increasing the pressure and density of the substance. An increased density allowed the plutonium to reach its critical mass, firing neutrons and allowing the fission chain reaction to proceed. To detonate the bomb, the explosives were ignited, releasing a shock wave that compressed the inner plutonium and led to its explosion.

red_dot