@kitkatchocolateyum: Азур (Azure) — персонаж из Roblox-игры Forsaken, которого планируют добавить в игру как нового убийцу. Его полное имя — Azurewrath. Известно, что: * он должен стать восьмым убийцей в игре; * на его груди находится символ Spawn; * до смерти Азур был обычным персонажем Roblox и занимался выращиванием цветов; * по сюжету он был близок с персонажем Two Time; * Two Time убил Азура, чтобы получить вторую жизнь, после чего Азур превратился в монстра; * предполагается, что его способности будут связаны с использованием ловушек.#азур#азуртаймы #azure #azuretime

𐙚┆₊៸៸ 🍰 𝚢𝚞𝚖!  𓈒 ⑅
𐙚┆₊៸៸ 🍰 𝚢𝚞𝚖! 𓈒 ⑅
Open In TikTok:
Region: KZ
Monday 13 July 2026 07:51:22 GMT
17164
3063
63
253

Music

Download

Comments

bombodrobilllka
Бомбодробилка[💥]🤘🏼😜 :
Было время когда я слушала эту песню целыми днями 😔
2026-07-14 04:36:12
242
cr1minal_chiken
Синабон🍪 :
Как помне новый лмс лучше
2026-07-14 18:40:39
15
siriuswebcore
Лейси?.. :
у меня сердце болит когда я слышу это
2026-07-14 20:18:09
4
laim_shurik
★Laim_Shurik★ :
Доктор, я опять слышу звуки из ада
2026-07-14 18:28:19
41
nia_0987ni1
𝙽𝚒𝚊𝄞 :
у меня хитсаунд с этой музыкой, имба
2026-07-13 10:55:57
85
eblan.ss0
𝘔𝘺𝘢𝘸𝘬𝘢 ッ :
У меня и сейчас гиперификс на это, я плачу
2026-07-14 10:12:30
7
user1efiwqms20
Помні і Джекс :
СЛУШАЛА 24/7❤️
2026-07-14 19:07:07
6
morning.dewart
morning.dewart :
у меня был гиперфикс на эту песню
2026-07-13 17:02:03
70
.k38368
Salat_XD :
я слышу слова
2026-07-14 08:15:51
26
rassvetk1
кирч :
странный лмс будет с новым лором, ведь ту тайм лишь с азуром поссорился
2026-07-14 12:52:04
6
fan1.de.nayeontwice
Jackeline[Kpoper&eyekon!)~☆.🦋 :
Como se elimina una story?💔
2026-07-14 20:02:28
0
c.ai_bots2024
что писать||кл рулит🌹 :
кто воздуханит рядом
2026-07-14 17:16:38
8
_.mimisa._04
纕ᙓᘻi〃 :
учёные нашли звуки из ада
2026-07-14 18:56:48
6
azurewrath._..nightshade
𝒢𓍢 ꒰ 𝓚ira! ❤︎ 𝓐zures ⸝⸝🪻꒱ :
AZURE
2026-07-14 09:11:26
1
may_skaya_
👾rosa🌹 :
дайте название песни пж
2026-07-14 21:14:19
0
agent_9993
агент дрим :
Хз, мне что тот лмс нравится что этот...
2026-07-14 20:28:12
0
mistress_177892akkarig
🚑Старшая медсестра🏥 :
Я рыгать начала извините , Я от латяо рыгаю
2026-07-14 19:07:14
3
_pelpishelm_
чо :
я сначала подумала что это типо крики когда Азура убивали💔
2026-07-13 17:09:29
13
bobidsq
Сушка:P :
ты в трубе блять?
2026-07-14 15:15:14
4
bestplayertwotime
—Леоанльдо Месси👣 :
у меня есть такое в тг ток на 1 час
2026-07-14 18:13:51
1
To see more videos from user @kitkatchocolateyum, please go to the Tikwm homepage.

Other Videos

Graham’s number is a famously enormous number that comes from a real mathematical problem, not from a puzzle or a joke. It was introduced by mathematician Ronald Graham in the 1970s while studying a problem in an area of mathematics called Ramsey theory, which investigates how order and patterns inevitably appear in large enough structures. What makes Graham’s number special isn’t just that it’s large—it’s how large it is. Numbers like a million, a billion, or even a googol (10^{100}) can all be written using ordinary decimal notation. A googolplex (10^{10^{100}}) is so large that you couldn’t physically write it out in the observable universe, but its definition is still simple. Graham’s number is vastly larger than a googolplex. In fact, even the number of digits in the first stage of its construction is far beyond anything that could ever be written or stored in the universe. To define Graham’s number, mathematicians use Knuth’s up-arrow notation, which is a shorthand for operations that grow much faster than exponentiation. A single up arrow means exponentiation, so 3 \uparrow 3 = 3^3 = 27. Two up arrows represent tetration, which builds towers of exponents. Three or four up arrows produce numbers that grow at an unimaginable rate. Graham’s number is defined through a sequence of 64 numbers. The first number in the sequence is already incomprehensibly large: G_1 = 3 \uparrow\uparrow\uparrow\uparrow 3 Then each following number uses the previous number as the number of arrows: G_2 = 3 \uparrow^{G_1} 3, meaning there are exactly G_1 arrows between the two 3s. This process continues until G_{64}, which is Graham’s number. Although this definition sounds abstract, it is completely precise. Every mathematician who follows the rules will arrive at exactly the same number. One surprising fact is that Graham’s number is finite. It is not infinity. Infinity is not a number at all but a concept describing something without bound. Graham’s number, despite being unimaginably huge, is still a specific integer. If you could somehow count forever fast enough, you would eventually reach it. Another surprising fact is that mathematicians know some properties of Graham’s number even though they cannot write it down. For example, they know its last ten decimal digits are: 2464195387 This is possible because number theory allows mathematicians to compute the ending digits without calculating the entire number. Historically, Graham’s number was once listed in the Guinness Book of World Records as the largest number ever used in a mathematical proof. However, it is no longer the largest number to appear in mathematics. Modern research has produced numbers defined by functions that grow much faster, such as TREE(3) and Rayo’s number, both of which are incomparably larger than Graham’s number. Despite being surpassed, Graham’s number remains one of the most famous large numbers because it has a clear definition, arose naturally in serious mathematical research, and provides an excellent example of how quickly mathematical functions can outgrow our everyday intuition about size. It serves as a reminder that there are many different “levels” of huge numbers, and that even numbers that seem impossibly large, like a googolplex, are tiny compared with some of the numbers encountered in advanced mathematics. #tlpur #iqmaxx #fyp #tcc #viral
Graham’s number is a famously enormous number that comes from a real mathematical problem, not from a puzzle or a joke. It was introduced by mathematician Ronald Graham in the 1970s while studying a problem in an area of mathematics called Ramsey theory, which investigates how order and patterns inevitably appear in large enough structures. What makes Graham’s number special isn’t just that it’s large—it’s how large it is. Numbers like a million, a billion, or even a googol (10^{100}) can all be written using ordinary decimal notation. A googolplex (10^{10^{100}}) is so large that you couldn’t physically write it out in the observable universe, but its definition is still simple. Graham’s number is vastly larger than a googolplex. In fact, even the number of digits in the first stage of its construction is far beyond anything that could ever be written or stored in the universe. To define Graham’s number, mathematicians use Knuth’s up-arrow notation, which is a shorthand for operations that grow much faster than exponentiation. A single up arrow means exponentiation, so 3 \uparrow 3 = 3^3 = 27. Two up arrows represent tetration, which builds towers of exponents. Three or four up arrows produce numbers that grow at an unimaginable rate. Graham’s number is defined through a sequence of 64 numbers. The first number in the sequence is already incomprehensibly large: G_1 = 3 \uparrow\uparrow\uparrow\uparrow 3 Then each following number uses the previous number as the number of arrows: G_2 = 3 \uparrow^{G_1} 3, meaning there are exactly G_1 arrows between the two 3s. This process continues until G_{64}, which is Graham’s number. Although this definition sounds abstract, it is completely precise. Every mathematician who follows the rules will arrive at exactly the same number. One surprising fact is that Graham’s number is finite. It is not infinity. Infinity is not a number at all but a concept describing something without bound. Graham’s number, despite being unimaginably huge, is still a specific integer. If you could somehow count forever fast enough, you would eventually reach it. Another surprising fact is that mathematicians know some properties of Graham’s number even though they cannot write it down. For example, they know its last ten decimal digits are: 2464195387 This is possible because number theory allows mathematicians to compute the ending digits without calculating the entire number. Historically, Graham’s number was once listed in the Guinness Book of World Records as the largest number ever used in a mathematical proof. However, it is no longer the largest number to appear in mathematics. Modern research has produced numbers defined by functions that grow much faster, such as TREE(3) and Rayo’s number, both of which are incomparably larger than Graham’s number. Despite being surpassed, Graham’s number remains one of the most famous large numbers because it has a clear definition, arose naturally in serious mathematical research, and provides an excellent example of how quickly mathematical functions can outgrow our everyday intuition about size. It serves as a reminder that there are many different “levels” of huge numbers, and that even numbers that seem impossibly large, like a googolplex, are tiny compared with some of the numbers encountered in advanced mathematics. #tlpur #iqmaxx #fyp #tcc #viral

About