Passive heat transport subsystems in handheld electronic devices

1 . A smartphone comprising: an outermost housing formed of a front surface, a rear surface opposite of the front surface, and a perimeter of the smartphone connecting the front surface to the rear surface; a plurality of electronic components contained in the outermost housing; a channel that is thermally coupled to the plurality of electronic components and forms a cavity extending continuously through the smartphone between two sides of the perimeter, the channel being configured to enable air contained in the cavity to absorb heat dissipated by the plurality of electronic components and enable an airflow from an external environment through the channel of the smartphone and back to the external environment; an air inlet of the cavity at one of the two sides of the perimeter, the air inlet being configured to accept air from the external environment; and an air outlet of the cavity at another of the two sides of the perimeter, the air outlet being configured to expel air heated by the plurality of electronic components to the external environment when the channel is oriented vertically relative to earth such that the heated air flows by natural convection from the air inlet toward the air outlet via the channel, wherein temperature of air is cooler at the air inlet compared to temperature of air at the air outlet. 2 . (canceled) 3 . The smartphone of claim 1 , wherein the heated air does not flow due to natural convection across the channel towards the air outlet when the channel is oriented horizontally relative to earth. 4 . The smartphone of claim 1 , wherein the channel is configured to accept heat generated by the plurality of electronic components located proximate to the channel. 5 . (canceled) 6 . (canceled) 7 . The smartphone of claim 1 , further comprising: a plurality of micro-channels configured to accept air from the external environment and expel air to the channel, wherein air expelled from the micro-channels is hotter than the air accepted by the micro-channels because the micro-channels are configured to contain air that accepts heat from the plurality of electronic components. 8 . The smartphone of claim 1 , further comprising: a heatsink disposed at the air outlet and being permeable to airflow, the heatsink being thermally coupled to the channel such that the heatsink dissipates heat from the heated air contained in the cavity of the channel to the external environment, wherein the heatsink includes a plurality of fin structures. 9 . The smartphone of claim 1 , further comprising: a thermosiphon configured to accept heat from the plurality of electronic components and transport the heat to the air outlet of the channel in accordance with thermosiphon principals. 10 . The smartphone of claim 1 , further comprising: a heat pipe configured to accept heat from the plurality of electronic components and transport the heat to the air outlet of the channel in accordance with heat pipe principals. 11 . The smartphone of claim 1 , further comprising: a heatsink disposed at the air outlet and being permeable to airflow, the heatsink being thermally coupled to the channel such that the heatsink dissipates heat from the heated air contained in cavity of the channel to the external environment, wherein the heatsink includes a plurality of fin structures; and a thermosiphon or heat pipe configured to accept heat from the plurality of electronic components and transport the heat to the air outlet of the channel, where the thermosiphon or heat pipe and the heatsink form a thermally continuous structure. 12 . The smartphone of claim 1 , further comprising: a forced convection unit operable to increase a rate of airflow in the channel. 13 . The smartphone of claim 1 , further comprising: a forced convection unit configured to activate and increase a rate of airflow in the cavity when each of the channel is oriented parallel to ground or a temperature of the smartphone exceeds a threshold temperature, and is configured to deactivate when the channel is oriented perpendicular to ground or the temperature of the smartphone is below the threshold temperature. 14 . The smartphone of claim 1 , further comprising: a forced convection unit operable to increase a rate of airflow in the channel; and a thermosiphon configured to accept heat from the plurality of electronic components and transport heat toward the air outlet of the channel in accordance with thermosiphon principals; and a heatsink permeable to air and thermally coupled to the channel such that the heatsink dissipates heat from the airflow to an external environment, the heat sink being disposed on the air outlet of the channel. 15 . A camera accessory of a smartphone, the camera accessory comprising: an outmost housing of the camera accessory; a plurality of cameras including a plurality of electronic components contained in the outmost housing; a channel that is thermally coupled to the plurality of electronic components and extends continuously through the camera accessory to form a cavity for airflow through the camera accessory, the channel being configured to enable air contained in the cavity to absorb heat dissipated by the plurality of electronic components and enable an airflow from an external environment through the channel of the camera accessory and back to the external environment; an air inlet of the channel formed by traversing the outmost housing, the air inlet being configured to enable the cavity to accept air from the external environment; and an air outlet of the channel formed by traversing the outmost housing, the air outlet being configured to expel air heated by the plurality of electronic components to the external environment when the channel is oriented perpendicular to earth such that the heated air flows in the cavity by natural convection from the air inlet to the air outlet of the channel, wherein temperature of air is cooler at the air inlet compared to temperature of air at the air outlet. 16 . The camera accessory of claim 15 , further comprising: a plurality of micro-channels configured to accept air from the external environment and expel air to the channel, wherein air expelled from the micro-channels is hotter than air accepted by the micro-channels because the air contained in the micro-channels are configured to accept heat from the plurality of electronic components. 17 . The camera accessory of claim 15 , further comprising: a forced convection unit operable to increase a rate of airflow in the channel; a thermosiphon configured to accept heat from the plurality of electronic components and transport the heat toward the air outlet of the channel in accordance with thermosiphon principals; and a heatsink permeable to air and thermally coupled to the channel such that the heatsink dissipates heat from the airflow to an external environment, the heatsink being disposed on the air outlet of the channel. 18 . A handheld electronic device comprising: a hollow channel extending through the handheld electronic device, the hollow channel being configured to enable air contained in the hollow channel to absorb heat dissipated by a plurality of electronic components contained in the handheld electronic device, and enable airflow from an external environment through the hollow channel and back to the external environment; an air inlet of the hollow channel traversing an outmost surface of the handheld electronic device, the air inlet being configured to accept air from the external environment; and an air outlet o