Material processing systems and methods

What is claimed is: 1. A material processing apparatus, comprising: a transmitter configured to irradiate an ore sample with a sub-millisecond pulse comprising at least one of a sub-millisecond microwave pulse and a sub-millisecond radiofrequency pulse in response to a command signal, the ore sample including a conductive mineral particle and a volume of a gangue; and a processing circuit coupled to the transmitter, wherein the processing circuit is configured to: specify the command signal for the transmitter, wherein the command signal varies based on a characteristic of the sub-millisecond pulse, wherein the characteristic includes a pulse length of the sub-millisecond pulse, wherein the processing circuit is configured to specify the pulse length based on at least one of (a) a thermal diffusivity of the volume of the gangue and (b) a thermal diffusion rate from the conductive mineral particle into the volume of the gangue; and provide the command signal to the transmitter such that the sub-millisecond pulse selectively deposits energy to at least one of melt and vaporize the conductive mineral particle of the ore sample. 2. The apparatus of claim 1 , wherein the characteristic includes a frequency of the sub-millisecond pulse. 3. The apparatus of claim 1 , wherein the processing circuit is configured to specify the pulse length based on a particle size of the conductive mineral particle. 4. A material processing apparatus, comprising: a transmitter configured to irradiate an ore sample with a sub-millisecond pulse comprising at least one of a sub-millisecond microwave pulse and a sub-millisecond radiofrequency pulse in response to a command signal, the ore sample including a conductive mineral particle and a volume of a gangue; and a processing circuit coupled to the transmitter, wherein the processing circuit is configured to: specify the command signal for the transmitter, wherein the command signal varies based on a characteristic of the sub-millisecond pulse, wherein the characteristic produces an energy deposition from the sub-millisecond pulse into the conductive mineral particle at a rate that is greater than a thermal diffusion rate from the conductive mineral particle into the volume of the gangue; and provide the command signal to the transmitter such that the sub-millisecond pulse selectively deposits energy to at least one of melt and vaporize the conductive mineral particle of the ore sample. 5. A material processing apparatus, comprising: a transmitter configured to irradiate an ore sample with a sub-millisecond pulse comprising at least one of a sub-millisecond microwave pulse and a sub-millisecond radiofrequency pulse in response to a command signal, the ore sample including a conductive mineral particle and a volume of a gangue; a processing circuit coupled to the transmitter, wherein the processing circuit is configured to: specify the command signal for the transmitter, wherein the command signal varies based on a characteristic of the sub-millisecond pulse; and provide the command signal to the transmitter such that the sub-millisecond pulse selectively deposits energy to vaporize the conductive mineral particle of the ore sample to produce a mineral vapor, wherein interaction between the mineral vapor and the ore sample at least partially weakens the volume of the gangue; and at least one of: a recovery system configured to collect at least a portion of the mineral vapor; and a reducer positioned to decrease the size of the ore sample. 6. The apparatus of claim 5 , further comprising the reducer positioned to decrease the size of ore sample. 7. The apparatus of claim 5 , wherein the transmitter is configured to selectively melt the conductive mineral particle to produce a mineral liquid and wherein interaction between the mineral liquid and the ore sample at least partially weakens the volume of the gangue. 8. The apparatus of claim 7 , further comprising the reducer positioned to decrease the size of the ore sample. 9. A material processing apparatus, comprising: a transporter configured to transfer an ore sample from a first position to a second position through a first zone, wherein the ore sample includes a conductive mineral particle and a volume of a gangue; a transmitter positioned to irradiate the first zone with a sub-millisecond electromagnetic pulse in response to a command signal; and a processing circuit coupled to the transmitter, wherein the processing circuit is configured to: specify the command signal for the transmitter, wherein the command signal varies based on a characteristic of the sub-millisecond electromagnetic pulse; and provide the command signal to the transmitter such that the sub-millisecond electromagnetic pulse selectively deposits energy to at least one of melt and vaporize the conductive mineral particle of the ore sample and produce a treated ore sample; a reducer positioned to decrease the size of the treated ore sample within a second zone to produce a reduced treated ore sample. 10. The apparatus of claim 9 , further comprising a monitor configured to evaluate a size distribution of the reduced treated ore sample and return a portion of the reduced treated ore sample having a size above a threshold value to the first zone. 11. A material processing apparatus, comprising: a transporter configured to transfer an ore sample from a first position to a second position through a first zone, wherein the ore sample includes a conductive mineral particle and a volume of a gangue; a transmitter positioned to irradiate the first zone with a sub-millisecond electromagnetic pulse in response to a command signal; a processing circuit coupled to the transmitter, wherein the processing circuit is configured to: specify the command signal for the transmitter, wherein the command signal varies based on a characteristic of the sub-millisecond electromagnetic pulse; and provide the command signal to the transmitter such that the sub-millisecond electromagnetic pulse selectively deposits energy to at least one of melt and vaporize the conductive mineral particle of the ore sample; and a recovery system, wherein the sub-millisecond electromagnetic pulse selectively deposits energy to at least partially vaporize the conductive mineral particle of the ore sample and produce a mineral vapor and a treated ore sample and wherein the recovery system is configured to collect at least a portion of the mineral vapor. 12. The apparatus of claim 11 , further comprising a reducer positioned to decrease the size of the treated ore sample within a second zone to produce a reduced treated ore sample. 13. The apparatus of claim 12 , further comprising a monitor configured to evaluate a size distribution of the reduced treated ore sample and return a portion of the reduced treated ore sample having a size above a threshold value to the first zone. 14. The apparatus of claim 12 , further comprising a second transporter configured to transfer the reduced treated ore sample from the reducer through a third zone. 15. The apparatus of claim 14 , further comprising a second transmitter and a second recovery system, wherein the second transmitter is positioned to irradiate the third zone with a second sub-millisecond electromagnetic pulse to vaporize a mineral of the reduced treated ore sample to produce a residual mineral vapor and wherein the second recovery system is configured to collect at least a portion of the residual mineral vapor.