Lemma 1. If
λ
\lambda
is a cardinal with cf
λ
>
ω
\lambda > \omega
, then
◻
λ
{\square _\lambda }
implies that there is a
λ
+
{\lambda ^ + }
-Aronszajn tree with an
ω
\omega
-ascent path, i.e. a sequence
(
x
¯
α
:
α
>
λ
+
)
\left ( {{{\bar x}^\alpha }:\alpha > {\lambda ^ + }} \right )
with each
x
¯
α
=
(
x
n
α
:
n
>
ω
)
{\bar x^\alpha } = \left ( {x_n^\alpha :n > \omega } \right )
a one-to-one sequence from
T
α
{T_\alpha }
, such that for all
α
>
β
>
λ
+
,
x
n
α
\alpha > \beta > {\lambda ^ + },x_n^\alpha
precedes
x
n
β
x_n^\beta
in the tree order for sufficiently large
n
n
. Lemma 2. If
λ
\lambda
is a cardinal with
cf
λ
=
ω
>
λ
\operatorname {cf} \lambda = \omega > \lambda
, then
◻
λ
{\square _\lambda }
implies that there is a
λ
+
{\lambda ^ + }
-Aronszajn tree with an
ω
1
{\omega _1}
-ascent path (replace
ω
\omega
by
ω
1
{\omega _1}
, above). Lemma 3. If
λ
\lambda
is an uncountable cardinal,
κ
\kappa
is regular,
κ
>
λ
,
cf
λ
≠
κ
,
T
\kappa > \lambda ,\operatorname {cf} \lambda \ne \kappa ,T
is a
λ
+
{\lambda ^ + }
-Aronszajn tree, and
(
x
i
α
:
i
>
κ
)
\left ( {x_i^\alpha :i > \kappa } \right )
is a one-to-one sequence from
T
ζ
(
α
)
{T_{\zeta \left ( \alpha \right )}}
with the property of ascent paths, where
ζ
:
λ
+
→
λ
+
\zeta :{\lambda ^ + } \to {\lambda ^ + }
is a monotone increasing function of
α
\alpha
, then
T
T
is nonspecial. Theorem 4. If
λ
\lambda
is uncountable, then
◻
λ
{\square _\lambda }
implies that there is a nonspecial
λ
+
{\lambda ^ + }
-Aronszajn tree. Theorem 5. If
λ
\lambda
is an uncountable cardinal,
κ
=
λ
+
\kappa = {\lambda ^ + }
, and
κ
\kappa
is not
(
w
e
a
k
l
y
c
o
m
p
a
c
t
)
L
{(weakly\;compact)^L}
, then there is a nonspecial
κ
\kappa
-Aronszajn tree.