Abstract:
A method, system and apparatus are described. The apparatus includes a first device to adjust a polarity associated with a thermoelectric (TEC) module. The adjustment is to control the flow of heat. The flow of heat is directed toward a thermal interface material (TIM) in order to melt the TIM up to an acceptable melt level. The apparatus further includes a second device to determine whether the TIM has melted up to the acceptable melt level. The apparatus includes an application device to apply the TIM to a heat sink if the TIM is melted has melted up to the acceptable melt level.

Description:
RELATED APPLICATION  
   This application is a divisional application of U.S. application Ser. No. 10/608,634, filed on Jun. 27, 2003, and entitled “Application and Removal of Thermal Interface Material” the priority of which is hereby claimed. 

   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The invention generally relates to heat transfer assembly, and more particularly to application and removal of thermal interface material (TIM). 
   2. Description of the Related Art 
   Integrated circuit (IC) devices and other electronic components are becoming increasingly faster, smaller, and thinner. Today&#39;s IC devices also come with added functionalities and capabilities, resulting in generating greater amounts of heat from the IC devices. As a result, IC packages are also getting smaller and are producing greater amounts of heat. The combination of producing greater heat and consuming greater resources, such as current, often results in lower reliability of the IC devices as maintaining the ideal temperature range becomes increasingly difficult. Furthermore, large amounts of heat produced by increasing number of electronic components, such as IC devices, may potentially damage individual electronic components, the IC package, and the equipment. Thus, many attempts have been made to improve the IC package so as to efficiently dissipate excessive heat. 
   Heat transfer mechanisms available today provide solutions by, for example, restricting the operation of IC devices to lower power levels, lower data rates, and/or lower operating frequencies. Conventional heat transfer mechanisms also have limited heat transfer capabilities due to size, location, and thermal limitations. Lacking an efficient heat transfer mechanism, the speed and power capabilities of the IC device and other electronic components may be severely limited. 
   Most heat transfer mechanisms employ heat transfer devices, such as heat sinks, to efficiently dissipate excessive heat. A heat sink is typically used as a conductor to dissipate excessive heat to prevent the IC device, and other heat generating electronic components, from overheating. The heat sink may be placed above the IC device with a thermal gap in between the heat sink and the IC device. The thermal gap may be filled with a TIM, such as grease, to provide the thermal conduction path between the heat sink and the IC device to improve heat transfer and dissipation. 
   A conventional TIM may include a gel, grease, or polymer-like material. However, the performance and reliability of the conventional TIM is typically not very good because of, for example, inherently low thermal conductivity. None of the conventional methods, apparatus, and systems provide for using a TIM that provides better reliability, performance, and thermal conductivity than the conventional TIM. 
   Furthermore, conventional methods, apparatus, and systems do not related to providing solutions for the application and removal of the TIM that may require a phase change when introduced to and removed from the heat sink. Conventional methods and apparatus are limited to reducing the current TIM thermal resistance, and requiring very high pressure to be applied on the IC package. The application of such high pressure negatively affects the reliability of the IC package and the TIM, resulting in lack of re-workability of the TIM, higher TIM resistance, and decreased TIM reliability. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The appended claims set forth the features of the present invention with particularity. The embodiments of the present invention, together with its advantages, may be best understood from the following detailed description taken in conjunction with the accompanying drawings of which: 
       FIG. 1  illustrates a cross-sectional view of a conventional integrated circuit package; 
       FIG. 2  illustrates an embodiment of a cross-sectional view of a heat transfer assembly; 
       FIG. 3  illustrates an embodiment of a close-up cross-sectional view of a heat transfer assembly; 
       FIG. 4  illustrates an embodiment of a cross-sectional view of a heat transfer assembly; 
       FIG. 5  illustrates an embodiment of a close-up cross-sectional view of a heat transfer assembly; 
       FIG. 6  is a flow chart illustrating an embodiment of a process for applying a thermal interface material (TIM); and 
       FIG. 7  is a flow chart illustrating an embodiment of a process for removing a thermal interface material (TIM). 
   

   DETAILED DESCRIPTION 
   A method and apparatus are described for application and removal of thermal interface material (TIM). Broadly stated, embodiments of the present invention provide for improving the application and removal of a TIM using heat control in a heat transfer assembly. 
   A system, apparatus, and method are provided for applying the TIM to and removing the TIM from a thermal gap of a heat transfer device, such as a heat sink. According to one embodiment, the thermal gap may refer to the area between the heat transfer device and the integrated circuit (IC) device in an IC package, and, according to one embodiment, the thermal gap may be considered a part of the heat transfer device. According to one embodiment, the TIM may be applied at the base of the heat transfer device. According to one embodiment, a phase change material (PCM) or metal-based TIM may be used to provide better conductivity, reliability, and performance by, for example, providing a better bonding between the TIM and various components of the IC package. 
   According to one embodiment, the polarity of a thermoelectric (TEC) module may be changed to change the direction of heat flow in the heat transfer device. According to one embodiment, changing the direction of heat flow may include reversing the direction of heat flow towards the TIM. According to one embodiment, by redirecting the flow of heat towards, for example, the metallic TIM, the temperature of the metallic TIM may be raised up to the melting temperature of the metal of the metallic TIM. According to one embodiment, the metallic TIM may be applied to the thermal gap or removed from the thermal gap of the heat transfer device with relative ease when the metal is soft or melted. 
   The embodiments of the present invention include various steps, which will be described below. The steps may be performed manually or using various hardware components or may be embodied in machine-executable instructions, which may be used to cause a processor or machine or logic circuits programmed with the instructions to perform the steps. Furthermore, the steps may be performed manually and/or automatically. 
   In the following description, for the purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be apparent; however, to one skilled in the art, based on the disclosure provided herein, that the embodiments of the present invention might be practiced without some of these specific details. For example, structural, logical, and electrical changes may be made without departing from the scope of the present invention. Moreover, it is to be understood that the various embodiments of the invention, although different, are not necessarily mutually exclusive. For example, a particular feature, structure, or characteristic described in one embodiment may be included within other embodiments. In other instances, well-known structures and devices are shown in block diagram form. 
     FIG. 1  illustrates a cross-sectional view of a conventional integrated circuit package. As illustrated the integrated circuit (IC) package (package)  100  may include an electronic component or circuit  102  (chip), such as an IC circuit device or a semiconductor device or a silicon chip, packaged (or coupled) with a printed circuit board (PCB)  106  and with a mounted heat transfer device, such as a heat sink  104 . The chip  102  may be the primary heat source for producing and emitting heat. Typically, the chip  102  may be coupled with a die pad  112  using an adhesive material  110 . The die pad  112  may rest on a board (not illustrated), such as a laminated board, having an insulation layer. Additional layers or surfaces or boards may be included and placed or stacked upon each other. The additional pattern layers may be electronically connected with the top of the chip  102  using wires. 
   As illustrated, the package may also include a ball grid array (BGA)  108  including a grid of solder balls, such as solder balls  114  and  116 , also known as solder interconnection balls or solder bumps, as its joints to connect the chip  102  with the PCB  106  using solder joints, such as solder joints  118  and  120 . Solder balls  114  and  116 , which may be placed in a selective pattern, such as in rows and columns, may be used to transmit electrical signals between the chip  102  and the PCB  106 . Solder balls may serve as ground or power source contacts. Furthermore, solder balls may be used to dissipate heat away from the chip  102  by, for example, transferring the heat to the various heat dissipating points on the PCB  106 . Solder joints  118  and  120  may also provide connection between the PCB  106  and the chip  102  via their connection with contacts in the PCB  106 , and with the chip  102  by vias, such as the vias  122 . 
   As illustrated, a heat transfer device  104  include a metal block or plate forming a heat dissipating element, such as the heat sink, may be coupled with the PCB  106 . The heat transfer device  104  may be coupled with the PCB  106  using multiple supports, such as supports  124  and  126 . There may be a gap, known as the thermal gap  128 , between the bottom surface  130  of the heat sink  104  and the top surface  132  of the chip  102 . Typically, a highly thermal conductive material may be used to fill the thermal gap  128  to dissipate the heat away from the chip  102  towards the heat sink  104 . The highly thermal conductive material, which is well known as thermal interface material (TIM), may typically include polymer, gel, and grease. The direction of the heat being dissipated from away from the chip  102  towards the heat sink  104  is illustrated by arrows  134  and  136 . 
     FIG. 2  illustrates an embodiment of a cross-sectional view of a heat-transfer assembly. A heat transfer or heat sink assembly (assembly)  200  may include a heat transfer device, such as the heat sink  204 . As illustrated, the heat sink  204  may be mounted on the heat source (chip)  202  and coupled with a printed circuit board (PCB) (not illustrated) to dissipate excessive heat away from the chip  202  and towards the heat sink  204 . The heat sink  204  may be mounted on the chip  202  such that there may be a gap, known as the thermal gap  228 , between the bottom surface of the heat sink  204  and the top surface of the chip  202 . According to one embodiment, thermal interface material (TIM)  238  may be applied to the thermal gap  228  provide better conductivity and reliability by dissipating excessive heat away from the chip  202  and thus, help cool the chip  202 . According to another embodiment, TIM  238  may be applied at the base of the heat sink  204 , but not necessarily in the thermal gap  228 . 
   Typically, a highly thermal conductive material may be used as TIM  238 . For example, TIM  238  may include inherently soft material, such as polymer, gel, or grease, to fill the thermal gap  228  to dissipate the heat away from the chip  202  towards the heat sink  204 . Inherently soft materials, such as polymer, gel, and grease, may not require a phase change when applied to or removed from the thermal gap  228 . According to one embodiment, TIM  238  may include a phase change material for providing better conductivity and reliability. Such phase change material may be wax-like and may require a phase change when applied to or removed from, for example, the thermal gap  228 . 
   According to one embodiment, TIM  238  may be metallic, including a solder-type material, such as indium (symbol: In), or indium alloy, or the like. According to one embodiment, metals with a melting temperature range of 60-300 degrees Celsius may be used as the TIM  238 . For example, indium having a melting temperature of 157 degrees Celsius or tin-silver (symbol: Sn—Ag) having a melting temperature of 226 degrees Celsius may be used. According to one embodiment, metallic TIM  238  may provide much better conductivity, reliability, and performance than a conventional TIM by, for example, providing a metallic bond between various components of the assembly  200 , such as between a copper, gold, or nickel-plated integrated or integral heat spreader (IHS) and a nickel-plated heat sink, such as the heat sink  204 . However, metallic TIM  238  may be inherently solid and may require phase change when applied to and removed from the heat sink  204 . 
   According to one embodiment, the assembly  200  may include a sealed vapor chamber  240  and heat exchanges or heat dissipating fins or thin base fins (fins)  244 . According to one embodiment, the vapor chamber  240  may include a phase change fluid when using phase change material refrigeration to dissipate heat away from the chip  202 . According to one embodiment, the assembly  200  may also include a thermoelectric element or module (TEC module)  246  positioned at the base of the heat sink  204  of the assembly  200 . According to one embodiment, the TEC module  246  at the base of the assembly  200  may be placed between the sealed vapor chamber  240  and the fins  244 . As illustrated, the TEC module  246  may have a cold side  248  in thermal contact with the vapor chamber  240  and a hot side  250  in thermal contact with the fins  244 . According to another embodiment, the assembly  200  may include one or more TEC modules  246  placed or positioned at various locations at the base of the assembly  200 , e.g., at base of the heat sink  204 . According to one embodiment, a TEC module  246  at the base of the assembly  200  may be used in the application and removal of the TIM  238 . 
   According to one embodiment, as illustrated by the arrows  252 , the direction of the heat flow may be from the chip  202 , passing the TIM  238 , through the vapor chamber  240 , and on towards the TEC module  246 . Stated differently, the heat flows away from the TIM  238  through the vapor chamber  240  passing the TEC module  246  towards the fins  244 , e.g., from the cold side  248  or the side of the vapor chamber  240 , towards the hot side  250  or the side of the fins  244 . According to one embodiment, polarity  256  may represent the polarity of the TEC module  246  during normal operating conditions of the assembly  200  and its various components. 
   According to one embodiment, the TEC module  246  may be used to decrease the temperature of the vapor chamber  240  and/or to increase the temperature of the fins  244  for improved efficiency. According to one embodiment, for a given heat sink base temperature, the TEC module  246  may allow more power to dissipate through, and lower processor temperature may be achieved while dissipating greater processor heat. 
   According to one embodiment, the TEC module  246  may be semiconductor-based and may refer to any device that operates as heat pump. For example, when voltage or current is applied to the TEC module  246 , heat may be transferred from a first side of the TEC module  246  to a second side of the TEC module  246 , cooling the first side and heating the second side. According to one embodiment, the amount of heat transferred may be a function of the applied voltage. 
   The fins  244  may include a heat exchange device or element or component. The fins  244  may include folded fins, parallel plates, extruded fins, offset strip fins, pin fins (staggered or in-line), or the like. According to one embodiment, the fins  244  may be made of an individual mesh piece. For example, the fins  244  may be made as folded fins formed from a single mesh sheet that may be folded, such as in the accordion style, to provide a plurality of parallel or generally parallel fins. The fins  244  may be attached to the rest of the heat sink  204  by soldering, welding, or brazing. 
   The chip  202  may include any computational or processing circuit, such as a microprocessor, a microcontroller, a graphics processor, a graphics card, a graphics chip, an electronic circuitry, a chipset, a power converter component or device, a digital signal processor (DSP), a complex instruction set computing (CISC) processor, a reduced instruction set computing (RISC) processor, or a very long instruction word (VLIW) processor. The chip  202  may be part of a computer system or physical machine, such as a mainframe computer, a handheld device, a workstation, a server, a portable computer, a set-top box, an intelligent apparatus or system or appliance, a virtual machine, or any other computing system or device. 
     FIG. 3  illustrates an embodiment of a close-up cross-sectional view of a heat transfer assembly. As illustrated, a heat transfer or heat sink assembly (assembly)  200  may include a heat transfer device, such as the heat sink  204 , mounted on or coupled with a heat source or chip (chip)  202 . The assembly  200  of  FIG. 2  may include a thermal interface material (TIM)  238  between the chip  202  and a sealed vapor chamber  240 . According to one embodiment, a thermoelectric element or module (TEC module)  246  may be placed at the base of the assembly  200  to provide additional support and aid in improving the application and removal of the TIM  238 . According to another embodiment, the assembly  200  may include one or more TEC modules  246  placed or positioned at various locations at the base of the assembly  200 . According to one embodiment, the TEC module  246  at the base of the assembly  200  may provide additional support and aid in the application and removal of the TIM  238 . 
   According to one embodiment, as illustrated by the arrows  252 , the direction of heat flow under normal operating conditions may be from the chip  202  towards the fins  244  through TEC module  246 . Stated differently, the heat flows away from the TIM  238  through the vapor chamber  240  passing the TEC module  246  towards the fins  244 , e.g., from the cold side  248  or the side of the vapor chamber  240 , towards the hot side  250  or the side of the fins  244 . According to one embodiment, polarity  256  may represent the polarity of the TEC module  246  during normal operating conditions of the assembly  200  and its various components. 
   Typically, a highly thermal conductive material may be used as TIM  238 . TIM  238  may include inherently soft material, such as polymer, gel, or grease, to fill, for example, the thermal gap  228  to dissipate the heat away from the chip  202  towards the heat sink  204 . Inherently soft material, such as polymer, gel, and grease, may not require a phase change when applied to or removed from the heat sink  204 . According to one embodiment, TIM  238  may include a phase change material for providing better conductivity and reliability. Such phase change material may be wax-like and may require phase change when applied to or removed from the heat sink  204 . 
   According to one embodiment, TIM  238  may be metallic, including solder-type material, such as indium (symbol: In), or indium alloy, or the like. According to one embodiment, metals with a melting temperature range of 60-300 degrees Celsius may be used. For example, indium having a melting temperature of 157 degrees Celsius or tin-silver (symbol: Sn—Ag), having a melting temperature of 226 degrees Celsius may be used as TIM  238 . According to one embodiment, metallic TIM  238  may provide much better conductivity, reliability, and performance than a conventional TIM by, for example, providing a metallic bond between various components of the assembly  200 , such as between a copper, gold, or nickel-plated integrated or integral heat spreader (IHS) and a nickel-plated heat sink, such as the heat sink  204 . However, metallic TIM  238  may be inherently solid and may require phase change when applied to and removed from the heat sink  204 . 
     FIG. 4  illustrates an embodiment of a cross-sectional view of a heat transfer assembly. As illustrated, a heat transfer device or heat sink assembly (assembly)  200  may include a heat transfer device, such as the heat sink  204 . As illustrated, the heat sink  204  may be mounted on a heat source (chip)  202  and coupled with a printed circuit board (PCB) (not illustrated) to dissipate excessive heat away from the chip  202  and towards the heat sink  204 . 
   The heat sink  204  may be mounted on the chip  202  such that there may be a gap, known as the thermal gap  228 , between the bottom surface of the heat sink  204  and the top surface of the chip  202 . Typically, a highly thermal conductive material, also known as thermal interface material (TIM)  238 , such as polymer, gel, or grease, may be used to fill the thermal gap  228  to dissipate the heat away from the chip  202  towards the heat sink  204 . According to one embodiment, TIM  238  may be used to dissipate excessive heat away from the chip  202  and thus, help cool the chip  202 . 
   According to one embodiment, TIM  238  may be metallic, including solder-type material, such as indium (symbol: In), or indium alloy, or the like. According to one embodiment, metals with a melting temperature range of from 60-300 degrees Celsius may be used. For example, indium having a melting temperature of 157 degrees Celsius or tin-silver (symbol: Sn—Ag) having a melting temperature of 226 degrees Celsius may be used as TIM  238 . According to one embodiment, metallic TIM  238  may provide much better conductivity, reliability, and performance than a conventional TIM by, for example, providing a metallic bond between various components of the assembly  200 , such as between a copper, gold, or nickel-plated integrated or integral heat spreader (IHS) and a nickel-plated heat sink, such as the heat sink  204 . However, metallic TIM  238  may be inherently solid and may require phase change when applied to and removed from a heat sink  204 . According to one embodiment, metallic TIM  238  may be applied in the thermal gap  228  between the heat sink  204  and the chip  202 . According to another embodiment, metallic TIM  238  may be applied at the base of the heat sink  204 , but no necessarily in the thermal gap  228 . 
   According to one embodiment, the assembly  200  may include a sealed vapor chamber  240  and heat exchanges or heat dissipating fins or thin base fins (fins)  244 . According to one embodiment, the vapor chamber  240  may include a phase change fluid when using phase change material refrigeration to dissipate heat away from the chip  202 . According to one embodiment, the assembly  200  may also include a thermoelectric element or module (TEC module)  246  positioned at the base of the heat sink  204  of the assembly  200 . According to one embodiment, the TEC module  246  at the base of the assembly  200  may be between the sealed vapor chamber  240  and the fins  244 . As illustrated, TEC module  246  may have a cold side  248  in thermal contact with the vapor chamber  240  and a hot side  250  in thermal contact with the fins  244 . According to another embodiment, the assembly  200  may include one or more TEC modules  246  placed or positioned at various locations at the base of the assembly  200 . According to one embodiment, the TEC module  246  at the base of the assembly  200  may provide support and aid in the application and removal of the TIM  238 . 
   According to one embodiment, as illustrated by the arrows  454 , the direction of the heat flow may be changed, e.g., reversed, with respect to, but not limited to, as illustrated in  FIGS. 2 and 3 . According to one embodiment, the TEC module polarity, such as the polarity  256  as illustrated in  FIGS. 2 and 3  may be changed to a different TEC module polarity, such as the polarity  458 , as illustrated here. Stated differently, polarity  256 , which may be referred to as the TEC module polarity during normal operating conditions of the assembly  200 , may be changed, e.g., reversed, to a new polarity, illustrated as the polarity  458 . According to one embodiment, the TEC module polarity  256  under normal operating conditions may be changed to the TEC module polarity  458  by, for example, reversing the terminals of the TEC module  246 , or a special device or equipment or apparatus may be used to reversed the polarity  256 , or the polarity  256  may be changed by making adjustments at and to the power source (not illustrated). 
   According to one embodiment, by changing the TEC module polarity, such as from  256  to  458 , the heat in the assembly  200  may also change its flow, such as reverse its flow. For example, the heat may flow from the TEC module  246  towards the TIM  238  via the vapor chamber  240 . Stated differently, the heat may change its course and flow from the cold side  460 , e.g., the side of the fins  244  towards the hot side  462 , e.g., the side of the vapor chamber  240  and the TIM  238 . According to one embodiment, the TEC module polarity  458  may represent the polarity of the TEC module  246  after the change in the TEC polarity  256  of  FIGS. 2 and 3  has been made. 
   According to one embodiment, the change in the heat flow in the assembly  200  directed towards, for example, the metallic TIM  238  may cause the metallic TIM  238  to melt or soften as the temperature caused the by heat flow into the TIM  238  rises to the melting temperature of the metallic TIM  238 . Stated differently, with changed polarity and reversed flow of heat, the TIM  238  may melt and become softer as it receives the heat flow. According to one embodiment, the polarity may be changed and the flow of heat reversed at the time of the application or attachment of the TIM  238  to facilitate easy application of the TIM  238  to the heat sink  204 , as the softer metallic TIM  238  may be easier to apply as opposed to a solid metallic TIM  238 . Similarly, according to one embodiment, the change of polarity and heat flow may be used at the time of the removal or detachment of the TIM  238  to facilitate easy removal of the TIM  238  from the heat sink  204 . As with regard to the application of the metallic TIM  238 , the softer metallic TIM  238  may be easier to remove from the heat sink  204  as opposed to a solid metallic TIM  238 . 
   According to one embodiment, the changing of the polarity and the flow of heat, may allow the fins  244  to function at their normal convection, e.g., the fan may not be needed to be powered. Furthermore, according to one embodiment, the TEC module  246  may be used by the users without any extra effort or training. According to one embodiment, the heat input by the TEC module  246  may be controlled using a separate circuit to, for example, maintain the reliability of the entire integrated circuit package and all of its components. 
   According to one embodiment, the TEC module  246  may be semiconductor-based and may refer to any device that operates as heat pump. For example, when voltage or current is applied to a TEC module  246 , heat may be transferred from a first side of the TEC module to a second side of the TEC module, cooling the first side and heating the second side. According to one embodiment, the amount of heat transferred may be a function of the applied voltage. 
   The fins  244  may include a heat exchange device or element or component. The fins  244  may include folded fins, parallel plates, extruded fins, offset strip fins, pin fins (staggered or in-line), or the like. According to one embodiment, the fins  244  may be made of an individual mesh piece. For example, the fins  244  may be made as folded fins formed from a single mesh sheet that may be folded, such as in the accordion style, to provide a plurality of parallel or generally parallel fins. The fins  244  may be attached to the rest of the heat sink  204  by soldering, welding, or brazing. 
   The chip  202  may include any computational or processing circuit, such as a microprocessor, a microcontroller, a graphics processor, a graphics card, a graphics chip, an electronic circuitry, a chipset, a power converter component or device, a digital signal processor (DSP), a complex instruction set computing (CISC) processor, a reduced instruction set computing (RISC) processor, or a very long instruction word (VLIW) processor. The chip  202  may be part of a computer system or physical machine, such as a mainframe computer, a handheld device, a workstation, a server, a portable computer, a set-top box, an intelligent apparatus or system or appliance, a virtual machine, or any other computing system or device. 
     FIG. 5  illustrates an embodiment of a close-up cross-sectional view of a heat transfer assembly. As illustrated, a heat transfer or heat sink assembly (assembly)  200  may include a heat transfer device, such as the heat sink  204 , mounted on or coupled with a heat source or chip (chip)  202 . The assembly  200  may include a thermal interface material (TIM)  238  between the chip  202  and a sealed vapor chamber  240 . According to one embodiment, a thermoelectric element or module (TEC module)  246  may be placed at the base of the assembly  200  to provide additional support and aid in improving the application and removal of the TIM  238 . According to another embodiment, the assembly  200  may include one or more TEC modules  246  placed or positioned at various locations at the base of the assembly  200 . According to one embodiment, the TEC module  246  at the base of the assembly  200  may provide additional support and aid in the application and removal of the TIM  238 . 
   According to one embodiment, metallic TIM  238  may provide much better conductivity, reliability, and performance than a conventional TIM by, for example, providing a metallic bond between various components of the assembly  200 , such as between a copper, gold, or nickel-plated integrated or integral heat spreader (IHS) and a nickel-plated heat sink, such as the heat sink  204 . However, metallic TIM  238  may be inherently solid and may require phase change when applied to and removed from a heat sink  204 . According to one embodiment, metallic TIM  238  may be applied in the thermal gap  228  between the heat sink  204  and the chip  202 . According to another embodiment, metallic TIM  238  may be applied at the base of the heat sink  204 , but no necessarily in the thermal gap  228 . 
   As illustrated by the arrows  454 , and as described in reference to  FIG. 4 , the direction of the heat flow may be changed, e.g., reversed, with respect to, but not limited to, as illustrated in  FIGS. 2 and 3 . According to one embodiment, the polarity  256  (of  FIGS. 2 and 3 ), which may be referred to as the TEC module polarity during normal operating conditions of the assembly  200 , may be changed, e.g., reversed, to a new polarity, illustrated as the polarity  458 . According to one embodiment, the TEC module polarity  256  under normal operating conditions may be changed to the TEC module polarity  458  by, for example, reversing the terminals of the TEC module  246 , or a special device or equipment or apparatus may be used to reversed the polarity  256 , or the polarity  256  may be changed by making adjustments at and to the power source (not illustrated). 
   According to one embodiment, the change in the heat flow in the assembly  200  directed towards, for example, the metallic TIM  238  may cause the metallic TIM  238  to melt or soften as the temperature caused the by heat flow into the TIM  238  rises to the melting temperature of the metallic TIM  238 . Stated differently, with changed polarity and reversed flow of heat, the TIM  238  may melt and become softer as it receives the heat flow. According to one embodiment, the polarity may be changed and the flow of heat reversed at the time of the application or attachment of the TIM  238  to facilitate easy application of the TIM  238  to the heat sink  204 , as the softer metallic TIM  238  may be easier to apply as opposed to a solid metallic TIM  238 . Similarly, according to one embodiment, the change of polarity and heat flow may be used at the time of the removal or detachment of the TIM  238  to facilitate easy removal of the TIM  238  from the heat sink  204 . As with regard to the application of the metallic TIM  238 , the softer metallic TIM  238  may be easier to remove from the heat sink  204  as opposed to a solid metallic TIM  238 . 
     FIG. 6  is a flow diagram illustrating an embodiment of a process for applying a thermal interface material. At processing block  602 , according to one embodiment, the normal operating polarity of a thermoelectric module or element (TEC module) may be changed, e.g., reversed. Stated differently, the TEC module polarity, which may be referred to as the TEC module polarity during normal operating conditions of the assembly, may be changed, e.g., reversed, to a new polarity. For example, the positive (+) TEC module terminal on the power supply may be switched to the negative (+) TEC module terminal and the negative (−) TEC module terminal may be switched to the positive (+) TEC module terminal. According to one embodiment, the TEC module polarity may be changed to the by, for example, reversing the terminals of the TEC module, or a special device or equipment or apparatus may be used, or the polarity may be changed by making adjustments at and to the power source. 
   At processing block,  604 , the direction of the heat flow may be changed as the TEC polarity has changed. According to one embodiment, the heat flow may change its path and flow towards the thermal interface material (TIM). With this change in the heat flow, heat may be applied to the TIM, such as a metallic TIM. According to one embodiment, TIM may include a phase change material for providing better conductivity and reliability. Such phase change material may be wax-like and may require phase change when applied to or removed from the heat sink. According to one embodiment, TIM may be metallic, including solder-type material, such as indium, or indium alloy, or the like. According to one embodiment, metals with a melting temperature range of from 60-300 degrees Celsius may be used. According to one embodiment, metallic TIM may provide much better conductivity, reliability, and performance than a conventional TIM by, for example, providing a metallic bond between various components of the heat transfer or heat sink assembly (assembly). However, metallic TIM may be inherently solid and require phase change when applied to and removed from a heat sink. 
   At processing block  606 , the temperature of the TIM may rise as a result of the heat flowing into the TIM, until the TIM is melted. At decision block,  608 , whether the TIM has melted is determined. According to one embodiment, with rising TIM temperature due to the heat flowing into the TIM, the TIM temperature may reach or get close to the melting temperature of, for example, the metallic TIM, causing the metallic TIM to melt and get softer. According to one embodiment, if the temperature has reached the melting temperature of the TIM and the TIM has melted, the melted TIM may be applied to the heat sink at processing block  610 . According to one embodiment, the TIM may be applied in the thermal gap between the heat sink and the chip, or the TIM may be applied to the base of the heat sink, but not necessarily in the thermal gap. An example may include an indium-based TIM reaching or getting close to a temperature of 157 degrees Celsius. According to one embodiment, the TIM may be applied using a dispenser or an applicator, such as an epoxy dispenser machine or a vacuum suction cup, or the like. According to one embodiment, if the temperature as not reached the melting point of the TIM or that the TIM has not yet melted, the process may continue at processing block  608 . 
     FIG. 7  is a flow diagram illustrating an embodiment of a process for removing a thermal interface material. At processing block  702 , according to one embodiment, the normal operating polarity of a thermoelectric module or element (TEC module) may be changed, e.g., reversed. Stated differently, the TEC module polarity, which may be referred to as the TEC module polarity during normal operating conditions of the assembly, may be changed, e.g., reversed, to a new polarity. 
   At processing block,  704 , the direction of the heat flow may be changed as the TEC polarity has changed. According to one embodiment, the heat flow may change its path and flow towards the thermal interface material (TIM). With this change in the heat flow, heat may be applied to the TIM, such as a metallic TIM. As described with reference to  FIG. 6 , according to one embodiment, a phase change material may be used as TIM for providing better conductivity and reliability. According to one embodiment, TIM may be metallic, including solder-type material, such as indium, or indium alloy, or the like, for, for example, providing better performance, conductivity, and reliability in comparison to a conventional TIM. According to one embodiment, metals with a melting temperature range of from 60-300 degrees Celsius may be used. Metallic TIM, however, may be solid and require phase change when applied to or removed from a heat sink. 
   At processing block  706 , the temperature of the TIM may rise as a result of the heat flowing into the TIM, until the TIM is melted. At decision block,  708 , whether the TIM has melted is determined. According to one embodiment, with rising TIM temperature due to the heat flowing into the TIM, the TIM temperature may reach or get close to the melting temperature of, for example, the metallic TIM, causing the metallic TIM to melt and get softer. For example, an indium-based TIM may get softer as the temperature reaches or gets close to 157 degrees Celsius. According to one embodiment, if the temperature has reached the melting temperature of the TIM and the TIM has melted, the melted TIM may be removed from the heat sink at processing block  710 . According to one embodiment, the TIM may be removed from the thermal gap between the heat sink and the chip, or the TIM may be removed from the base of the heat sink, but not necessarily from the thermal gap. According to one embodiment, the TIM may be removed using a remover device or machine, such as a vacuum suction cup, or the like. According to one embodiment, if the temperature has not reached the melting point of the TIM or that the TIM has not yet melted, the process may continue at processing block  708 . 
   While certain exemplary embodiments of the invention have been described and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of and not restrictive on the broad aspects of various embodiments of the invention, and that these embodiments not be limited to the specific constructions and arrangements shown and described, since various other modifications are possible. It is possible to implement the embodiments of the invention or some of their features in hardware, programmable devices, firmware, software, or a combination thereof.