I shall show now that there is no solution to the recursive equations with 

(1)  $P_j \gt 0, j = 1, 2, 3, ...$ 

First from 

$\alpha P_1 = P_2 + P_3$

we conclude 

$\alpha \gt 0$

Notice also the $P_0$ appears only in the relation

$\alpha P_0 = P_1$    

which shows that 

$P_0 \gt 0$ as well, but $P_0$ does not appear in the normalization.
Therefore we consider it as a mere abrevíation for $P_1/ \alpha $.

Now we transform the recursive relation into a standard form, which we define here to be one in which an element with a specific index is defined in terms of elements with smaller indices.

Define

(2) $Q_i = P_{i+1}+P_{i+2}+..., i = 0,1,2,...$

As a sum over positive quantities we have 

$Q_i \gt 0, i = 0, 1, 2, ...$

The inversion of (2) is

(3) $P_i = Q_{i-1} - Q_i	, i = 1, 2, ...	$

Now the equations become

$\alpha P_j = Q_j - Q_{2j+1}, j =1, 2, 3, ...    $

Using (3) we get

$\alpha (Q_{j-1}-Q_j) = Q_j - Q_{2j+1}$

or

(4)   $Q_{2j+1} = (1+\alpha ) Q_j - \alpha  Q_{j-1},    j = 1, 2, ...$     

This is now a recursive relation in standard form.

The inital values are

$Q_0 = P_1 + P_2 + ... = 1$

because of the normalization condition.

And

$Q_1 = 1 - P_1 = 1 - \alpha  P_0$

can be considered as a free parameter in the interval (0,1).

Before we solve (4) we observe that it defines only the elements with an odd index.

Therefore we let 

$Q_{2k} = C_k > 0, k = 1, 2, ...$

with positive $C_k$

Performing now the first few steps of the solution to (4) the Reader will find that

$P_{10} = - C_5 - \alpha  (1+\alpha ) Q_1$

But this is a negative quantity, and the contradiction proves the statement.