So it is not about complex as it is not only said but proven from the
definition of complex numbers.
It is not the definition, it is a consequence of a definition that I've
shown you numerous times. You are a liar.
Which leads to immediate inconsistencies. This property is contradictory.
This is utter bullshit. As are all your your fantasies. Build on top of
your ignorance, hypocrisies, stupidity and arrogance.

Contradictory, thus impossible.
If i^2=-1 then (i^2)^2 = (-1)^2 = 1 =  i^4

You have to understand that if we consider this equivalent case of
g(x) = x^4 + 9/4 and we visualize the complex roots as follows:

https://www.desmos.com/calculator/4mhohrcxlg

We're superimposing a real slice of the graph in the Cartesian plane on
top of Complex plane where we visualize the complex roots of the polynomial.

In order to understand why these are the roots of the polynomial g(x)
in the complex numbers, we have to expand our view to 3D:

https://www.desmos.com/3d/ykhhcpb3xz

Where we can visualize that polynomial as a function that maps complex
numbers to complex numbers as a combination of two surfaces in 3D
(one red surface for the real component of the output of the function
and an orange surface for the imaginary component of the output of the
function).
We can press the icons in front of the corresponding items in the list
on the left to temporarily hide those surfaces to identify the locations
in the complex plane where both components are equal to zero to see that
those are exactly the complex roots of the polynomial g(x) in the
complex number system.

(x-(+1+𝑖)⋅3/√2)⋅(x-(+1-𝑖)⋅3/√2)⋅(x-(-1+𝑖)⋅3/√2)⋅(x-(-1-𝑖)⋅3/√2) =
x⁴+81

In real and in complex numbers,
if a⋅b⋅c⋅d = 0
then one of a,b,c,d is 0
otherwise, a⋅b⋅c⋅d ≠ 0

If x⁴+81 = 0
and a⋅b⋅c⋅d = x⁴+81
then one of
a = x-(+1+𝑖)⋅3/√2 = 0
b = x-(+1-𝑖)⋅3/√2 = 0
c = x-(-1+𝑖)⋅3/√2 = 0
d = x-(-1-𝑖)⋅3/√2 = 0
is true.

Hence,
x ∈ {(+1+𝑖)⋅3/√2, (+1-𝑖)⋅3/√2, (-1+𝑖)⋅3/√2, (-1-𝑖)⋅3/√2}
Therefore, despite appearances,
your question is not "What is x?"
and it is not "what is a complex number?"

Your question is
"How can it be possible
for one person to speak to another
and be understood?"

The possibility of understanding is
greatly facilitated where
that which a speaker means by a word and
that which a listener thinks they mean by it
are in conformity.

This is not a deep philosophical point,
This is similar to noting that
phone calls with non.operating phones
are completely unsatisfactory.
A point doesn't need to be deep to be true.
Your question assumes a certain common background,
because that's how language works.
If your question was "How do I get to the post office?"
but you didn't admit the usual definitions of
'left', 'right', and so on,
odds are you don't get to the post office,
but that would have nothing to do with
the directions you were given.
I think you are asking why 𝐢²=-1
and why not = something else.

Most of the answer is that
we want a 2.dimensional field which extends
the 1.dimensional field of the real numbers.
That is to say, we want 2.dimensional
addition '+' and multiplication '⋅'
which satisfy the same laws which
our 1.dimensional '+' and '⋅' satisfy:
⎛ associativity and commutativity for both,
⎜ identities 𝟎 𝟏, inverses -𝐱 𝐱⁻¹ except 𝟎⁻¹,
⎝ distributivity of '.' over '+'

We have what we want if
we have a vector 𝐯 not on the real axis such that,
for this 2.dimensional multiplication '⋅'
𝟏⋅𝟏 = 𝟏
𝟏⋅𝐯 = 𝐯
𝐯⋅𝟏 = 𝐯
𝐯⋅𝐯 = -α𝟏-2β𝐯
such that α > β²

Pick 𝐯 ∈ ℝ×(ℝ\{0}), β, α > β²
Define
𝐯⋅𝐯 = -α𝟏-2β𝐯
(a𝟏+b𝐯)⋅(c𝟏+d𝐯) = ac𝟏+(ad+bd)𝐯+bd(𝐯⋅𝐯)

We have what we want,
a 2.dimensional field extending ℝ

However,
suppose 𝐯 ≠ ⟨0,1⟩ and 𝐯⋅𝐯 ≠ -𝟏
Then 𝐯 ≠ 𝐢

But 𝐢 still exists,//////////////////
determined by choices 𝐯, β, α
𝐢 = ±(𝐯+β𝟏)/(α-β²)¹ᐟ² (either works)
𝐯 = ±(α-β²)¹ᐟ²𝐢-β𝟏

Each a𝟏+b𝐯 has a corresponding a′𝟏+b′𝐢
and vice versa.
𝟏⋅𝟏 = 𝟏
𝟏⋅𝐢 = 𝐢
𝐢⋅𝟏 = 𝐢
𝐢⋅𝐢 = -𝟏
(a𝟏+b𝐢)⋅(c𝟏+d𝐢) = (ac-bd)𝟏+(ad+bd)𝐢
in the usual way.
For me, the definition of 'left' must be
extended to all directions.
Wish me luck!
The proposed system do not have
2.dimensional '+' and '⋅' satisfying:
⎛ associativity and commutativity for both,
⎜ identities 𝟎 𝟏, inverses -𝐱 𝐱⁻¹ except 𝟎⁻¹,
⎝ distributivity of '.' over '+'

I don't know what you mean here?

Actually, it's quite straightforward wrt getting at the roots for a
target number. Even using signed integers for the power.

The n-ary roots for (-1.873444+0i)?

here is the output from my program wrt the 4'th power:

roots[0] = (0.827266,0.827266)
roots[1] = (-0.827266,0.827266)
roots[2] = (-0.827266,-0.827266)
roots[3] = (0.827266,-0.827266)

raised[0] = (-1.87344,-1.63782e-07)
raised[1] = (-1.87344,-4.46812e-08)
raised[2] = (-1.87344,-1.74197e-06)
raised[3] = (-1.87344,1.05711e-06)

[...]
To the 13'th power with higher precision:

roots[0] = (1.01898,0.251156)
roots[1] = (0.7855438,0.6959311)
roots[2] = (0.3721492,0.9812768)
roots[3] = (-0.1265003,1.041824)
roots[4] = (-0.5961701,0.8637015)
roots[5] = (-0.9292645,0.4877156)
roots[6] = (-1.049476,5.945845e-16)
roots[7] = (-0.9292645,-0.4877156)
roots[8] = (-0.5961701,-0.8637015)
roots[9] = (-0.1265003,-1.041824)
roots[10] = (0.3721492,-0.9812768)
roots[11] = (0.7855438,-0.6959311)
roots[12] = (1.01898,-0.251156)

raised[0] = (-1.873444,2.294307e-16)
raised[1] = (-1.873444,4.016197e-15)
raised[2] = (-1.873444,4.475059e-15)
raised[3] = (-1.873444,1.606015e-15)
raised[4] = (-1.873444,2.064877e-15)
raised[5] = (-1.873444,9.179548e-15)
raised[6] = (-1.873444,9.63841e-15)
raised[7] = (-1.873444,4.132072e-15)
raised[8] = (-1.873444,4.590934e-15)
raised[9] = (-1.873444,1.170561e-14)
raised[10] = (-1.873444,2.214818e-14)
raised[11] = (-1.873444,1.262333e-14)
raised[12] = (-1.873444,2.306591e-14)