Self-cooling greenhouse for hot climate

We claim: 1. A roof for a greenhouse, comprising: a pair of facades connected to one another along a first edge of each façade of the pair, wherein each façade comprises an internal glass wall and an external glass wall in a parallel plane to the internal glass wall and separated from the internal glass wall by a first distance, wherein the distance is configured to permit passage of a heat transfer liquid; a reflector along the first edge, wherein the pair of facades are connected to one another via the reflector. 2. The roof of claim 1 , further comprising: an adsorber tube configured to convey the heat transfer liquid from the pair of facades along a focus of the reflector, wherein the reflector comprises a parabolic reflector. 3. The roof of claim 1 , wherein the internal glass wall comprises a first face, facing the external glass wall, and wherein the first face of the internal glass wall comprises a reflective surface configured to reflect solar radiation into the heat transfer liquid when in operation. 4. The roof of claim 3 , wherein the reflective surface comprises a textured surface having a texture. 5. The roof of claim 4 , wherein the texture comprises pyramids. 6. A greenhouse, comprising: a roof configured to adsorb thermal energy from the Sun to an interior of the greenhouse using a heat transfer liquid; and a heat exchange system configured to receive the heat transfer liquid and to recover the thermal energy from the heat transfer liquid, wherein the roof comprises a pair of facades connected to one another along a first edge of each façade of the pair; and a reflector along the first edge, wherein the pair of facades are connected to one another via the reflector. 7. A greenhouse, comprising: a roof configured to adsorb thermal energy from the Sun to an interior of the greenhouse using a heat transfer liquid; and a heat exchange system configured to receive the heat transfer liquid and to recover the thermal energy from the heat transfer liquid, wherein the roof comprises a pair of facades connected to one another along a first edge of each façade of the pair; and a reflector along the first edge, wherein the pair of facades are connected to one another via the reflector, and wherein each façade comprises an internal glass wall and an external glass wall in a parallel plane to the internal glass wall and separated from the internal glass wall by a first distance, wherein the distance is configured to permit passage of the heat transfer liquid. 8. The greenhouse of claim 7 , further comprising: an adsorber tube configured to convey the heat transfer liquid from the pair of facades along a focus of the reflector, wherein the reflector comprises a parabolic reflector. 9. The greenhouse of claim 7 , wherein the internal glass wall comprises a first face, facing the external glass wall, and wherein the first face of the internal glass wall comprises a reflective surface configured to reflect solar radiation into the heat transfer liquid when in operation. 10. The greenhouse of claim 9 , wherein the reflective surface comprises a textured surface having a texture. 11. The greenhouse of claim 10 , wherein the texture comprises pyramids. 12. The greenhouse of claim 6 , wherein the heat transfer liquid is configured to reflect or absorb at least one undesired band or wavelength of visible light based on a color of the heat transfer liquid. 13. A greenhouse, comprising: a roof configured to adsorb thermal energy from the Sun to an interior of the greenhouse using a heat transfer liquid; and a heat exchange system configured to receive the heat transfer liquid and to recover the thermal energy from the heat transfer liquid, wherein the heat exchange system comprises a pair of reactors comprising a first reactor and a second reactor, wherein the reactors comprise an adsorbent configured to adsorb the heat transfer liquid as adsorbate. 14. The greenhouse of claim 13 , wherein the pair of reactors are configured to operate alternatingly, with a first reactor in a heating and increasing pressure phase while a second reactor is in a cooling and pressure reduction phase, and then the first reactor in the cooling and pressure reduction phase while the second reactor is in the heating and increasing pressure phase. 15. The greenhouse of claim 13 , wherein the heat exchange system comprises a reservoir of the heat transfer liquid, an evaporator, the pair of reactors, and a compressor in fluid communication with one another via a plurality of valves. 16. The greenhouse of claim 15 , wherein a heat exchanger in the evaporator is configured to cool liquid that circulates through the interior of the greenhouse to control an interior temperature of the greenhouse.