Switchable sorption materials

1 . Method for decreasing the desorption enthalpy of a discharged high enthalpy sorption material that comprises a sorbed sorbate and that is at least partially discharged, wherein said method comprises a step 1 ) of reacting said discharged high enthalpy sorption material in a redox reaction to provide a discharged low enthalpy sorption material. 2 . Method according to claim 1 , wherein said redox reaction comprises oxidation or reduction of the discharged high enthalpy sorption material. 3 . Method according to the previous claims, wherein said redox reaction is carried out by providing electrical energy to the discharged high enthalpy sorption material. 4 . Method for operating a thermochemical energy storage device, wherein said method comprises decreasing the desorption enthalpy of a discharged high enthalpy sorption material by step 1 ) in accordance with any of the previous claims. 5 . Method according to claim 4 , wherein step 1 ) is followed by a step 2 ) of at least partially charging the discharged low enthalpy sorption material to provide an at least partially charged low enthalpy sorption material and a desorbed sorbate, wherein said charging comprises heating the discharged low enthalpy sorption material. 6 . Method according to claim 5 , wherein step 2 ) is followed by a step 3 ) of reacting said charged low enthalpy sorption material in a redox reaction to provide a charged high enthalpy sorption material, preferably wherein the redox reaction in step 3 ) is the reverse reaction of the redox reaction of step 1 ). 7 . Method according to claim 6 , wherein step 3 ) is followed by a step 4 ) of at least partially discharging said charged high enthalpy sorption material by supplying a sorbate in order to provide said discharged high enthalpy sorption material and heat. 8 . Method according to any of claims 5 - 7 , wherein said method comprises a step 2 ′) of at least partially discharging the charged low enthalpy sorption material by supplying the sorbate in order to give the discharged low enthalpy sorption material and heat. 9 . Method for generating electrical energy from heat, wherein said method comprises: a step 4 ′) of at least partially charging the discharged high enthalpy sorption material to provide an at least partially charged high enthalpy sorption material and a desorbed sorbate, wherein said charging comprises heating the discharged high enthalpy sorption material; a step 3 ′) of reacting the provided charged high enthalpy sorption material in a redox reaction to provide a charged low enthalpy sorption material; a step 2 ′) of at least partially discharging the provided charged low enthalpy sorption material by supplying the sorbate in order to give a discharged low enthalpy sorption material and heat; followed by a step 1 ′) of reacting the provided discharged low enthalpy sorption material in a redox reaction to provide a discharged high enthalpy sorption material and electrical energy. 10 . Method according to any of the previous claims, wherein said sorption material comprises polycyclic aromatic hydrocarbon such as perylene and/or a salt comprising Fe(CN) 6 ) 3− as anion, H 2 PtCl 6 , H 3 Fe(CN) 6 , ferrocene, Pt(NH 3 ) 2 Cl 4 , Co(NH 3 ) 6 , or variations thereof with other metal ions such as Pt, Fe, Pd, Co. 11 . Method according to any of the previous claims wherein the sorption material comprises a molecular framework such as a metal organic framework (MOF), covalent organic framework (COF), polymer-organic framework (POF), or combinations thereof, preferably wherein the salt according to the previous claim is positioned within the molecular framework. 12 . Method according to any of the previous claims, wherein the sorbate comprises a compound selected from the group consisting of water, methanol, ethanol, ammonia, CO, CO 2 and/or other small molecules that can sorb to the sorption material, or a combination thereof, preferably wherein the sorbate is water. 13 . Thermochemical energy storage device comprising a sorption material having at least two desorption enthalpy states, which correlate to at least two oxidation states of which one oxidation state correlates to a higher desorption enthalpy than one or more of the other oxidation states, more preferred which is adapted such that it can be operated in a method according to any of the previous claims. 14 . Thermochemical energy storage device according to the previous claim, wherein said sorption material is placed in an electrochemical cell and is in electrical contact with an electrode such as an anode or cathode of said electrochemical cell, preferably wherein said electrochemical cell comprises a Swiss-roll cell. 15 . Thermochemical energy storage device according to any of claims 13 - 14 , further comprising a liquid storage compartment comprising a condenser and/or evaporator unit and an energy storage compartment comprising the sorption material, and a heat exchanger that is thermally connected to the sorption material.