Post on 09-Jun-2020
NMR Spectrometer Hardware NMR Spectrometer Hardware
Manoj NaikManoj NaikNMR Facility, TIFRNMR Facility, TIFR
Workshop on NMR & its applicationsWorkshop on NMR & its applicationsTIFR, MumbaiTIFR, Mumbai
November 23, 2009 November 23, 2009
Principle of NMR
Nuclear Magnetic Resonance
ω = γ∗B
A Simplified 60 MHzA Simplified 60 MHzNMR SpectrometerNMR Spectrometer
TransmitterReceiver
Probe
hν
SN
RF Detector Recorder
RF (60 MHz)Oscillator
~ 1.41 Tesla (+ / - ) a few ppm
absorpt ion signal
MAGNETMAGNET
CONTINUOUS WAVE (CW) METHODCONTINUOUS WAVE (CW) METHOD
The magnet ic f ield is “scanned” from a low f ield strength to a higher f ield strength while a constantbeam of radiofrequency (cont inuous wave) is supplied at a f ixed frequency (say 100 MHz).
Using this method, it requires several minutes to plotan NMR spectrum.
THE OLDER, CLASSICAL METHOD
SLOW, HIGH NOISE LEVEL
PULSED FOURIER TRANSFORM PULSED FOURIER TRANSFORM (FT) METHOD(FT) METHOD
THE NEWER COMPUTER- BASED METHOD
The excitat ion pulse, the data collect ion (FID), and the computer- driven Fourier Transform (FT) take only a few seconds.
Most protons relax (decay) from their excited states very quickly (within a second).
The pulse and data collect ion cycles may be repeatedevery few seconds.
Many repet it ions can be performed in avery short t ime, leading to improved signal …..
FASTLOW NOISE
Bloch‘s Laboratory in Stanford 1949
First NMR Signal In1946
NMR in 1964
HFX90
NMR Spectrometer in 1970NMR Spectrometer in 1970
AM console
NMR Spectrometer in 1985NMR Spectrometer in 1985
Routine NMR Spectrometer in 2000Routine NMR Spectrometer in 2000
NMR Spectrometer Schematic
Spectrometer Layout
NMR Spectrometer hardware componentsNMR Spectrometer hardware components
1. Magnet1. Magnet2. RT Shims2. RT Shims3. Field Frquency Lock3. Field Frquency Lock4. Probes4. Probes5. Transmitters5. Transmitters6. Preamplifiers6. Preamplifiers7. Receiver7. Receiver8. Digitiser8. Digitiser9. Host Computer9. Host Computer
Type of Magnets
1: Permanent Magnet: Weak
2: Electromagnet: Bulky & Power Consuming
3: Superconducting Magnet: Compact
Superconducting Magnet
• Compact & Efficient• Ability to support high current density• Niobium-titanium for low field < 9 Tesla• Niobium tin for high field : expensive,brittle• Multifilamentary embedded in cu matrix• For better stability & less diamagnetism• Operated at 4.20K upto 700MHz• Operated at 20K above 700MHz
Magnet Coil
Cryostat Cutview
800 MAGNET CRYOSTAT Adjustment Screw for
Needle ValveQuench Valves
Pump Cryostat arrangement
Supercon magnet
• SC material Al5 + NbTi• Proton frequency 800.13 MHz• Central field 18.79 Tesla• He capacity 1200 litres (350+850)• Hold time > 56 days• Liq. N capacity 450 litres
System Liquid Helium Liquid Nitrogen
Boil offrate
Refill Volume Total Volume
Boil off rate
Refill volume Total Volume
500 MHz 35 ml/hour 100 Lit/3month
286 Lit 400 ml/hour 200 Lit/21days 286 Lit
600 MHz 35 ml/hour 80Lit/2month
195 Lit 250 ml/hour 135 Lit/21days 200 Lit
700 MHz 45ml/hour 162Lit/5month
257 Lit 455ml/hour 229Lit/21days 286 Lit
800 MHz 220 ml/hour 200Lit. /month
1200 Lit 750 ml/hour 250 Lit/15days 400 Lit
Cryogenics data for the NMR magnets
RT Shims
• Homogenous field essential for good lineshape • Variation in Magnetic field with Position• NMR frequency is proportional to field results
in distorted lineshape• To create homogenous field Shim coils are
placed in vicinity of sample • Shim currents strength adjusted by looking at
spectra to nullify field gradient
Field Homogeneity
Classification of Shims
• Axial or spinning shims … Z1,Z2,Z3,Z4…• Non-axial or non spinning shims … X,Y, XY
NMR Probes
NMR Probe
NMR probes
• HR Probes with ATM• High Resolution Probes with Automatic
Tuning and Matching(ATM)
• 5mm TXI … 1H/13C/15N/2H• 5mm BBI … 1H/2H/ BB
Cryoprobe
• The CryoProbe is a high-performance cryogenically cooled probe developed for high-resolution applications. It has improved signal/noise (S/N) ratios obtained by reducing the operating temperature of the coil and the pre-amplifier. The dramatic increase in the S/N ratio by a factor of 3-4, as compared to conventional probes, leads to a possible reduction in experiment time of up to 16 or a reduction in required sample concentration by a factor of up to 4.
• Linear behavior in power response • Gradient capability • CryoProbes are available as Triple Resonance, Enhanced Dual, Quad
Nucleus Probes, or Dual Inverse configurations at 400 MHz and higher
• All high resolution probes have a 2H lock circuit
Cryoplatform
• The CryoPlatform's main purpose is to provide the cooling infrastructure needed for the operation of cryogenic probes.
• Components of the CryoPlatform consists of a CryoCooling Unit and a Helium Compressor. The Cryocooling Unit, the heart of the cooling system is a Gifford McMahon cryocooler which is driven by pressurized helium supplied by the helium compressor. Cooling CryoProbes is accomplished with a closed-looped helium gas flow via a flexible transferline. The CryoCooling unit has dedicated electronics control and monitors the entire system during all phases of operation. It has an automatic error handling and safety shutdown functions.
Cryoplatform
Variable temperature
• In general– stable temperature (during experiment)– Controlled air flow over sample – Cooler and Heater are used to control the sample temperature- Thermocouple are used to sense sample
temp.
Low temperature
Moderately low: BCU-05 cooling unitHR- and MAS-Version (pressure)cools gas stream typically by 65 Ktemperature range: approx. -15°C to +50°C
really low: heat exchangerMAS version for VTN, WVT, DVTHR version for DVTcooling down of heat exchanger only underdry N2 gas
VT gas
N2 from boil-off device:dry, oil freelow pressure fluctuation inert
! Caution !! Look after fresh air !
! O2 warning system where required !
Compressed gas from compressor:pay attention to dew point and oil content (0.0 %)condensation of O2 at low temperaturerisc of oxidation at high temperaturepressure fluctuation
Probe and magnet protection
transfer tube
shimsystem “frame cooling“
NO ice nor heat at O-rings!
Probe and magnet protection
flush gas (ambient temperature) forshimsystem probehead (“frame cooling“)transfertube
critical parameters:high temperature: shim foils: T ≤ 70 °Clow temperature: in case of icing of O-rings risc of leakage of vacuum and quench!
Slow heating and cooling!
For heating and cooling consider thermal burden on probe
using a ramp of 6 to 10 degrees per minute is recommended
AQS REF-22 Block Diag.
d1
PW
FIDd1
SelectiveExcitation
NCO0 NCO2 NCO3 NCO0NCO1
NoFrequency F1+ ∆ F F1 Lo = F1 + 22MHz
NoFrequency
Simple Pulse SequenceSimple Pulse Sequence
NCO0Zero AmplitudeZero Frequency
NCO1W1 AmplitudeW1 Frequency
NCO2W2 AmplitudeW2 Frequency
NCO3W3 AmplitudeW3 Frequency
16x16 bit
MULTIPLIERDAC
CONVERTER
UPX
DIGITALCONTROLFROMFCU3
MODWn
Frequency MULT
RFOUT
SHAPEDDS
NCO = Numeric Controlled Oscillator.DDS = Direct Digital Synthesis.
ϕW1 1
ϕW1 2
ϕW1 3Σ
ϕW2 1
ϕW2 2
ϕW2 3Σ
ϕW3 1
ϕW3 2
ϕW3 3Σ ϕ Information
13-23MHz 3-1100MHz
Example of a 10-bit ROM tableExample of a 10-bit ROM table
0
2 = 6 4 K1 6
U P D O W N
U P D O W NI N V E R T E DS I G N
( b i t 1 6 )
( b i t 1 5 )
1 6 K( 1 4 b i t )
O n l y t h e f i r s t 1 / 4 o f t h e c o m p l e t e s i n e p e r i o d i s i n t h e R O M .T h e o t h e r q u a r t e r s a r e o b t a i n e d b y s y m m e t r y .
ROM table for 16 bitROM table for 16 bit
Phase Coherent:
Phase Continuous:
Phase Resetted:
NCO1 NCO2 NCO1
NCO1 NCO2 NCO1
NCO1 NCO2 NCO1 NCO2
Reset Reset
F1 F1+ ∆ F F1
F1 F1+ ∆ F F1 F1+ ∆ F
Flexible Frequency GenerationFlexible Frequency Generation
Blockdiagram of the SGUBlockdiagram of the SGU
TIMING
Pulse Duration: Minimum 50ns
Delay Duration: Minimum 50ns
Resolution 12.5ns
FREQUENCY
Range 3-1100MHz
Bandwidth of each Channel 3-1100MHz
Resolution <0.005Hz or 34bit
Switching Time
<+-2.5MHz Steps < 300ns
Timing and Frequency SpecificationsTiming and Frequency Specifications
PHASE
Phase resolution < 0.006° or 16bit
Phase switching time < 300ns
AMPLITUDE
Modulation (MOD) Range 96dB or 16bit
Resolution < 0.01dB up to 54dB
< 0.05dB up to 60dB
Level (MULT) Range 90dB
Resolution 0.1dB
Amplitude Switching Time 50ns
Next Event: Phase + Amplitude 100ns
Phase and Amplitude SpecificationsPhase and Amplitude Specifications
Amplifier
Amplifier
• overshoot– measured in % of pp voltage
• only little for short pulses
• ripple– measured in % of pp voltage
• only little for short pulses– low frequency ripple:
» comes from insufficient power supply– high frequency ripple:
» comes from RF impurities
• droop– measured in % of pp voltage
• important for long pulses and pulse trains
Characterisation of Pulse ShapesCharacterisation of Pulse Shapes
• on/off ratio– measured in dB
• important for noise reasons
• rise and fall time– from 10 % to 90 % ca. 100 ns
• not much of a concern, because it is determined by the narrowest component (which is the probe)
Characterisation of Pulse ShapesCharacterisation of Pulse Shapes
Transmitter Specification
Amplifier
Probe
Multiplexer
Preamplifier
Controller
Preamplifier designPreamplifier design
Top: wiring of amplifier, probe, and receiver (preamplifier)bottom left: switching under influence of a pulse (> 700 mV)bottom right: switching under influence of an NMR signal
Passive RF switchingPassive RF switching
Linear Pre-amp Specification
Receiver
RX22 Receiver:
Intermediate Frequency IF 22MHz. FID input from Preamplifier. Receiver output is audio frequency Channel A and B (quadrature) into digitizer.
RX22 Receiver:
Intermediate Frequency IF 22MHz. FID input from Preamplifier. Receiver output is audio frequency Channel A and B (quadrature) into digitizer.
Quadrature Detection
Digital to Analogue Conversion (ADC)
RXAD
• Does four main function … To amplify signal from HPPR Demodulation of RF signal to AF range To match the input range of ADC To digitize quadrature signal• Specification … Frequency range: 5…1072MHz Gain range: ………… 93dB in 1dB steps ADC resolution ……. 200KHz …. 20Bit 5MHz …….16Bit Data rate ….560Mbits/s
0-62.5kHz-100kHz 62.5kHz 100kHz
SAMPLING WINDOW
DIGITALFILTER20 kHz
ANTI-ALIASINGANALOGFILTER125 kHz
FkHz
Image
SWH Oversampling200 kHz
SWH2
Signal fullysuppressed
by Digital Filter SWH2
(After Decimation)
SWH(Before
Decimation)
CONVENTIONALANALOGFILTER
SW=20 kHz
10kHz-10kHz
Digital FilteringDigital Filtering
Digital Receiver Unit does following fucntion
Interface to two ADC channel
Capture peak values for ‘receiver gain adjust (rga)’
Automatic DC offset calibration (AutoZeroCompensation), digital phase control, Digital quadrature detection, Digital filtering & Decimation of NMR signals, accumulation and acquisition &
Data transfer to workstation via ethernet
Diagnosis & access to the DRU relies on HTTP & HTML enabling service access just by any web browser
DRU
AQS Avance AV OneBay
AQS CCU10
AQS CCU10 Block Diag.
CCU10 Specification
• RISC based cpu operating @ 100MHz• Ethernet link @ 100MHz half duplex• 10 RS232 CHANNEL• 2 RS485 CHANEL• 64Mb DRAM
Timing Control Unit TCU3
• to synchronize and control the timing of the RCU, FCU’s and GCU• to send frequency information to the FCUs via the F bus• to generate various front panel switching signals used in external amplifiers, QNP Pneumatic Unit, BSMS, etc.• to provide the RCU and GCU with a 40MHz TTL clock signal• to generate the RCUGO signal for the RCU and the AQS signal for the GCU
The TCU3 is used ….
• The timing of the TCU3 is implemented using an 80MHz internal clock (this signal is generated on board from the 20MHz of the REF22 board)
TCU3
Frequency Generation Unit
• Digital control of all aspects of frequency, phase and amplitude• Real-time control of all gating signals generated on the SGU• LVDS (low voltage differential signal) link between the FCU3 and SGU• The FCU3 can be viewed as the digital section of the SGU• One FCU3 contains four independent channels• No jumper-settings required due to auto configuration• No on-board DDS generation - this is performed by the SGU
FCU3
FCU / SGU LVDS Interface
Twisted Pair4x7 bit at 20MHz
560Mbit/s
20MHz(50ns)
Low Voltage Differential Signaling
FCU3 SGU
NMR Consol
The RF Part