Sahlqvist formulas are built up from implications, where the consequent is positive and the antecedent is of a restricted form.

• A boxed atom is a propositional atom preceded by a number (possibly 0) of boxes, i.e. a formula of the form ${\displaystyle \Box \cdots \Box p}$  (often abbreviated as ${\displaystyle \Box ^{i}p}$  for ${\displaystyle 0\leq i<\omega }$ ).
• A Sahlqvist antecedent is a formula constructed using ∧, ∨, and ${\displaystyle \Diamond }$  from boxed atoms, and negative formulas (including the constants ⊥, ⊤).
• A Sahlqvist implication is a formula A → B, where A is a Sahlqvist antecedent, and B is a positive formula.
• A Sahlqvist formula is constructed from Sahlqvist implications using ∧ and ${\displaystyle \Box }$  (unrestricted), and using ∨ on formulas with no common variables.

${\displaystyle p\rightarrow \Diamond p}$ 

Its first-order corresponding formula is ${\displaystyle \forall x\;Rxx}$ , and it defines all reflexive frames

${\displaystyle p\rightarrow \Box \Diamond p}$ 

Its first-order corresponding formula is ${\displaystyle \forall x\forall y[Rxy\rightarrow Ryx]}$ , and it defines all symmetric frames

${\displaystyle \Diamond \Diamond p\rightarrow \Diamond p}$  or ${\displaystyle \Box p\rightarrow \Box \Box p}$ 

Its first-order corresponding formula is ${\displaystyle \forall x\forall y\forall z[(Rxy\land Ryz)\rightarrow Rxz]}$ , and it defines all transitive frames

${\displaystyle \Diamond p\rightarrow \Diamond \Diamond p}$  or ${\displaystyle \Box \Box p\rightarrow \Box p}$ 

Its first-order corresponding formula is ${\displaystyle \forall x\forall y[Rxy\rightarrow \exists z(Rxz\land Rzy)]}$ , and it defines all dense frames

${\displaystyle \Box p\rightarrow \Diamond p}$ 

Its first-order corresponding formula is ${\displaystyle \forall x\exists y\;Rxy}$ , and it defines all right-unbounded frames (also called serial)

${\displaystyle \Diamond \Box p\rightarrow \Box \Diamond p}$ 

Its first-order corresponding formula is ${\displaystyle \forall x\forall x_{1}\forall z_{0}[Rxx_{1}\land Rxz_{0}\rightarrow \exists z_{1}(Rx_{1}z_{1}\land Rz_{0}z_{1})]}$ , and it is the Church–Rosser property.

${\displaystyle \Box \Diamond p\rightarrow \Diamond \Box p}$ 

This is the McKinsey formula; it does not have a first-order frame condition.

${\displaystyle \Box (\Box p\rightarrow p)\rightarrow \Box p}$ 

The Löb axiom is not Sahlqvist; again, it does not have a first-order frame condition.

${\displaystyle (\Box \Diamond p\rightarrow \Diamond \Box p)\land (\Diamond \Diamond q\rightarrow \Diamond q)}$ 

The conjunction of the McKinsey formula and the (4) axiom has a first-order frame condition (the conjunction of the transitivity property with the property ${\displaystyle \forall x[\forall y(Rxy\rightarrow \exists z[Ryz])\rightarrow \exists y(Rxy\wedge \forall z[Ryz\rightarrow z=y])]}$ ) but is not equivalent to any Sahlqvist formula.

When a Sahlqvist formula is used as an axiom in a normal modal logic, the logic is guaranteed to be complete with respect to the basic elementary class of frames the axiom defines. This result comes from the Sahlqvist completeness theorem [Modal Logic, Blackburn et al., Theorem 4.42]. But there is also a converse theorem, namely a theorem that states which first-order conditions are the correspondents of Sahlqvist formulas. Kracht's theorem states that any Sahlqvist formula locally corresponds to a Kracht formula; and conversely, every Kracht formula is a local first-order correspondent of some Sahlqvist formula which can be effectively obtained from the Kracht formula [Modal Logic, Blackburn et al., Theorem 3.59].

• L. A. Chagrova, 1991. An undecidable problem in correspondence theory. Journal of Symbolic Logic 56:1261–1272.
• Marcus Kracht, 1993. How completeness and correspondence theory got married. In de Rijke, editor, Diamonds and Defaults, pages 175–214. Kluwer.
• Henrik Sahlqvist, 1975. Correspondence and completeness in the first- and second-order semantics for modal logic. In Proceedings of the Third Scandinavian Logic Symposium. North-Holland, Amsterdam.