A method of servicing a wellbore may comprise providing a treatment fluid comprising a carrier fluid and hollow particles, wherein the hollow particles may comprise an outer wall that encapsulates a gas. The method may further comprise introducing the treatment fluid into a wellbore annulus and trapping at least a portion of the treatment fluid in the wellbore annulus. The carrier fluid may degrade the outer wall of the hollow particles in the wellbore annulus and release the encapsulated gas.

A method for reducing lost circulation in a subterranean formation. The method includes providing a treatment fluid comprising a base fluid and a lost circulation material comprising brown mud. The treatment fluid is introduced into a wellbore within the subterranean formation such that at least a portion of the brown mud bridges openings in the subterranean formation to reduce loss of fluid circulation into the subterranean formation.

A method for reducing lost circulation in a subterranean formation. The method includes providing a treatment fluid comprising a base fluid and a lost circulation material comprising brown mud. The treatment fluid is introduced into a wellbore within the subterranean formation such that at least a portion of the brown mud bridges openings in the subterranean formation to reduce loss of fluid circulation into the subterranean formation.

Preparing a treatment fluid comprising a base fluid and magnetic proppant particulates, wherein the magnetic proppant particulates comprise proppant particulates at least partially coated with a stabilization agent and magnetic particles, and preparing a spacer fluid comprising a base fluid, a gelling agent, and a breaker. Introducing the treatment fluid and the spacer fluid intermittently into a subterranean formation comprising a fracture so as to alternate placement of the magnetic proppant particulates in the treatment fluid with the spacer fluid in the fracture, and activating the magnetic particles, wherein the activated magnetic particles cause the magnetic proppant particulates to agglomerate. Propping open the fracture with the magnetic proppant particulates, and activating the breaker in the spacer fluid so as to at least partially remove the spacer fluid from the fracture, thereby leaving behind substantially magnetic proppant particulate-free channels between the magnetic proppant particulates.

Preparing a treatment fluid comprising a base fluid and magnetic proppant particulates, wherein the magnetic proppant particulates comprise proppant particulates at least partially coated with a stabilization agent and magnetic particles, and preparing a spacer fluid comprising a base fluid, a gelling agent, and a breaker. Introducing the treatment fluid and the spacer fluid intermittently into a subterranean formation comprising a fracture so as to alternate placement of the magnetic proppant particulates in the treatment fluid with the spacer fluid in the fracture, and activating the magnetic particles, wherein the activated magnetic particles cause the magnetic proppant particulates to agglomerate. Propping open the fracture with the magnetic proppant particulates, and activating the breaker in the spacer fluid so as to at least partially remove the spacer fluid from the fracture, thereby leaving behind substantially magnetic proppant particulate-free channels between the magnetic proppant particulates.

Wellbore synthesis techniques are disclosed suitable for use in geothermal applications. Embodiments are provided where open hole drilled wellbores are sealed while drilling to form an impervious layer at the wellbore/formation interface. The techniques may be chemical, thermal, mechanical, biological and are fully intended to irreversibly damage the formation in terms of the permeability thereof. With the permeability negated, the wellbore may be used to create a closed loop surface to surface geothermal well operable in the absence of well casing for maximizing thermal transfer to a circulating working fluid. Formulations for the working and drilling fluids are disclosed.

Wellbore synthesis techniques are disclosed suitable for use in geothermal applications. Embodiments are provided where open hole drilled wellbores are sealed while drilling to form an impervious layer at the wellbore/formation interface. The techniques may be chemical, thermal, mechanical, biological and are fully intended to irreversibly damage the formation in terms of the permeability thereof. With the permeability negated, the wellbore may be used to create a closed loop surface to surface geothermal well operable in the absence of well casing for maximizing thermal transfer to a circulating working fluid. Formulations for the working and drilling fluids are disclosed.

Dual-purpose additives that may be used as viscosifying agents and surface active agents in fluids, subterranean treatments and oilfield operations are provided. In one embodiment, the methods comprise: providing a treatment fluid comprising a base fluid and a polymeric dual-purpose additive comprising a base polymer comprising a plurality of monomer units, and one or more hydrophobic groups bonded to at least one of the monomer units; introducing the treatment fluid into at least a portion of a subterranean formation; and depolymerizing at least a portion of the dual-purpose additive to form one or more surface active fragments, each of the surface active fragments comprising one or more of the hydrophobic groups bonded to one or more of the monomer units.

Dual-purpose additives that may be used as viscosifying agents and surface active agents in fluids, subterranean treatments and oilfield operations are provided. In one embodiment, the methods comprise: providing a treatment fluid comprising a base fluid and a polymeric dual-purpose additive comprising a base polymer comprising a plurality of monomer units, and one or more hydrophobic groups bonded to at least one of the monomer units; introducing the treatment fluid into at least a portion of a subterranean formation; and depolymerizing at least a portion of the dual-purpose additive to form one or more surface active fragments, each of the surface active fragments comprising one or more of the hydrophobic groups bonded to one or more of the monomer units.

The effectiveness of expansive cement systems may be diluted when, during a well cementing operation, commingling takes place between the cement slurry and a spacer fluid, a drilling fluid, or both. Incorporating expansive agents in the spacer fluid or drilling fluid may reduce or negate the loss of expansion at the cement slurry/spacer interface or the cement slurry/drilling fluid interface, thereby promoting zonal isolation throughout the cemented interval.