Investing in the top range motherboard should afford a few privileges. It should come with extra features, extra components in the box, and where possible the manufacturer should put time and effort into better performance. The ASUS Z97-Deluxe (NFC & WLC) tips the scales at $400, but comes with Thunderbolt 2, an NFC connection system, a Wireless Charging system, dual SATA Express, dual Ethernet ports, 2T2R 802.11ac WiFi, M.2. support and a total of 10 SATA/USB 3.0 ports.

ASUS Z97-DELUXE Overview

After I tested the Z97-Deluxe, I almost considered titling the review ‘Everything But The Kitchen Sink’, in light of the depth ASUS has gone to ensure that a normal ATX motherboard has as much functionality as possible. The Deluxe is going to be as near as an everything motherboard as you might get, with dual NIC + 802.11ac 2T2R WiFi, two Thunderbolt 2 ports via an add-in card, NFC, Wireless Charging, two SATA Express ports, M.2 support and 10 SATA/USB – and at $400 it should be critically analyzed. $400 might seem like an upper price limit for a Z97 motherboard, as anything more sounds a bit much.  This is perhaps why we do not have a PLX chip for 4-way PCIe, a feature ASUS has left to its Z97-WS, which we will review in due course. This might mark a change in ASUS’ design, leaving 4-way PCIe devices to the workstation series, the LGA 2011 (Ivy Bridge-E) series and the gaming motherboards (Maximus Extreme). The Z97-Deluxe supports two-way SLI and three-way CrossFire, which should accommodate most LGA 1150 users not wanting a workstation motherboard.

Normally a lot of flak is aimed towards high pricing motherboards, especially in this enthusiastic segment when the motherboards cost more than the CPUs (i7-4770K currently $340, i5-4670K is $240). For such a price the motherboard has to offer something special and different than the rest of the range, and perhaps a few unique features that are not on any other product. The Z97-Deluxe (NFC & WLC) does this in its bundling: the included NFC and Wireless Charging utilities and the dual-port Thunderbolt 2 card add a large part of that value. The Z97-Deluxe without these additions is only $290, putting an exact $110 value on these add-ons. This in turn means that the users of the Z97 Deluxe (NFC & WLC) are keen to use these tools, and most likely on a regular basis. These tools can be used in other motherboards, and might be sold separately, but as they are in this bundle then they should probably be used with this motherboard. But that makes it a little different when the motherboard contains features that are disabled if the Thunderbolt card is used.

One of the confusing aspects of Z97 is how the chipset is arranged. With the introduction of SATA Express and M.2 on the motherboard, both requiring PCIe lanes and SATA ports, it almost becomes a case of picking and choosing. If a user wants the functionality of one feature, it might disable another. This is also true for the Z97-Deluxe:

So for example, if a user wants to use the dual Thunderbolt 2 card, it is suggested that the BIOS be adjusted such that the final PCIe slot uses x4 lanes from the chipset. This in turn disables the ASMedia SATA Express controller (one SATAe port) and the ASMedia USB 3.0 controller. If the final PCIe slot is set at x2, then only the SATA Express controller is disabled. In order to use the ASMedia SATAe port, the last PCIe slot must be disabled completely. On top of this, the M.2 slot and the other SATA Express slot share PCIe lanes. If we use one, the other is disabled.

This means the user has a choice: if you use two SATAe drives, or SATA drives in the SATAe ports, then this disables M.2, two rear USB 3.0 ports and the final PCIe slot. Z97 feels more like a game of musical chairs which on the one hand is exacerbated by the storage options but calms down a bit when we realize that the hardware to exploit them is still a couple of months away from release.

If we move all these extras aside and just consider the motherboard on its own, we get newer features like the EZ XMP switch (helps enable XMP without using the BIOS) alongside the storage, as well as Crystal Sound 2 which is the updated layout of the Realtek ALC1150 codec (meaning isolated PCB, EMI shield, filters and headphone amplifiers with DTS support). Perennial features now part of the ASUS fold such as USB BIOS Flashback, EPU, TPU, 4-pin fan headers that support DC+PWM modes, Wi-Fi Go! and DirectKey are all here, although DirectKey (the ability to restart into the BIOS) moves from a button to header.

The ASUS BIOS and software are also updated for Z97. Both take advantage of features I have been pushing for a while, such as fan profiling with accurate graphs and visual presets in the BIOS. While I think a part of the aesthetic element of the BIOS has taken a step back from Z87, the new functionality in the automatic overclocking allows users to choose a combination of cooling and workload for the BIOS to push the CPU. The software is updated to 5-Way Optimization, adding in an overclock-per-software feature called Turbo App. The automatic overclocking in the OS also allows adjusting of the stress element of the test, a much needed feature.

Benchmarks point the Z97-Deluxe as leading the way for integrated audio, with some of the best dynamic range and THD+N numbers we have ever seen after a driver update fixed a minor issue (similar to the one on our previous Z97 review) relating to heavy distortion at 100% speaker volume. Power consumption at idle seems high, but at load is low. The USB Turbo mode gives us some of the best USB 2.0 numbers we have seen, and manual overclocking got our CPU to 4.6 GHz quite easily. Other CPU and GPU benchmarks put the Z97-Deluxe (NFC & WLC) in the same regions as any of the other motherboards, putting the price increase firmly in terms of upgraded components, more functionality and the added NFC/WLC/Thunderbolt 2 extras. Users who buy the Z97-Deluxe (NFC & WLC) will have to specifically need those extras in order to justify the cost.

Visual Inspection

For the previous series of motherboards, ASUS adopted an off-color gold for its motherboards – a sort of yellow/mustard hybrid for Z87. For Z97 it has changed again, this time towards a more metallic dulled gold with a brushed look, similar to the brushed aluminum perspective of more design conscious fashion brands. The heatsinks are the main recipients of this style change, with the power delivery heatsink on the board sporting an ‘ASUSDESIGN’ motif.

The rear panel does not have this new color scheme, which is unfortunate. I think having the rear silver parts the same metallic design might homogenize the look. Nevertheless, the socket area is up against Intel specifications on all sides. The heatsinks on three sides are sufficiently low for most big air heatsinks, however should a user decide to place a large heatsink blowing left-right as well as using tall DRAM (such as G.Skill TridentX) there might be an altercation. The heatsink to the left and below the socket are joined by a heatpipe. Typically a heatsink below an 8-series motherboard was indicative of a PLX chip, however ASUS is using this merely to extend surface area for heat dissipation.

The socket area has access to five of the six fan headers on the motherboard. To the bottom left near the rear panel are two 4-pin chassis headers, and to the top in between the heatsink and the DRAM slots are a CPU fan header and a CPU_OPT header for liquid cooler setups. The fifth header within reach of the socket is above the 24-pin ATX power connector, and the final header on board is at the bottom next to the USB 2.0 headers. All the fan headers on board are 4-pin and capable of DC or PWM fan functionality.

The DRAM slots use single-sided latch mechanisms to make it easier to remove modules when large PCIe devices are installed. This also means that users should take care to ensure that the DRAM modules are pushed in sufficiently. At the top right of the motherboard is the MemOK button, allowing users to reboot into the system without losing CPU frequencies and just resetting the DRAM to stock speeds. Below this is a new feature on ASUS motherboards – the ‘EZ XMP’ switch. For users who do not want to enter the BIOS but still want full speed from the memory, this switch should be enabled to enable the Extreme Memory Profile of the memory used.

Below the 24-pin ATX power connector are two USB 3.0 headers, both powered by an ASMedia ASM1074 USB 3.0 hub from one of the chipset USB 3.0 ports. Below this is the complex SATA port arrangement, starting with two SATA 6 Gbps from an ASMedia controller. Next are four SATA 6 Gbps ports from the chipset, and then two SATA Express connectors that contain four more SATA 6 Gbps ports. As explained by the diagram in the middle of the board, the bottom SATAe port is powered by the chipset (two SATA 6 Gbps ports and x2 lanes) and the top SATAe is via the ASMedia ASM1065E controller. This controller takes two lanes from the chipset and can allocate them to the SATA ports or the SATAe as required. Note that this SATAe slot shares bandwidth with the PCIe 2.0 x4 slot on board as well as the two rear USB 3.0 ports from an ASMedia controller. Next to the SATAe is an M.2 slot which also requires x2 lanes and two SATA ports, which it shares with the first SATA Express meaning only one can be occupied at the same time. Confused yet?

The bottom of the motherboard gives an array of headers and switches. Underneath the M.2 is an extended TPU switch, one click gives an automatic overclock based on CPU multipliers and the other boosts the CPU multiplier and BCLK. Next to the TPU is the EPU, which when enabled helps to keep the power consumption of the system down. One of the changes with Z97 over Z87 is with the small header below, labeled DRCT for DirectKey. This is a header that when shorted will boot the system into the BIOS – something that a reviewer or overclocker might have frequent use of. I would prefer it as a button rather than a header, just because it means I have to find something to short the pins. To the left of the DRCT header is a T_SENSOR1 header, allowing users to add in their own thermocouple for temperature monitoring and fan control. To the left of this are two headers for the SATA Express ports, in order to pass a base clock through to the device should the drive require it. There is one for each of the SATA Express ports as required.

To the left of the TPU switch is another header for increasing the voltage limits to the system. For extreme overclockers using liquid nitrogen, normal voltage limits are not enough to squeeze every bit of performance out of the motherboard, and to stop regular users burning CPUs with 1.9 volts, ASUS has relegated this option to those users who can also adjust an onboard header.

At the bottom edge of the motherboard is the normal range of headers – the front panel header, a fan header, two USB 2.0 headers, a TPM header, power/reset buttons, a two-digit debug display for POST codes, a CLR_CMOS button for resetting the BIOS, a BIOS Flashback button, the Thunderbolt header and the front audio header.

The left hand side of the motherboard contains the audio subsystem which ASUS has upgraded since Z87. Crystal Sound 2 houses a Realtek ALC1150 codec with an EMI shield, as well as separating the PCB between analog and digital signals. The filters and amplifiers help adjust the signal, including a de-pop circuit, to give some of our best audio results for onboard audio. The audio also has DTS II support.

Next to the audio is the PCIe layout, offering an x1, x16 (x8), x1, x1, x8, x1 and x4 slots. The final x4 slot can be adjusted as x4, x2 or disabled as it shares bandwidth with the second SATAe port and the USB 3.0 ports on the rear panel. In order to use the bundled Thunderbolt 2 card in the package, this slot has to be in x4 mode.

The rear panel uses all three digital outputs possible from an LGA1150 CPU, configured as a HDMI, a DisplayPort and a mini-DisplayPort. The 802.11ac 2T2R Broadcom module is also on the rear panel in the form of Wi-Fi Go, next to a set of four USB 2.0 ports. The back panel uses two USB 3.0 ports from an ASMedia controller (shares bandwidth with the final PCIe slot on the motherboard) and four USB 3.0 ports from the chipset. The two Ethernet ports are both from Intel, one I218V and the other I211-AT. Finally the audio jacks from the ALC1150 are also here.

Board Features

ASUS Z97-Deluxe (NFC + WFC)
Price US Link
Size ATX
CPU Interface LGA-1150
Chipset Intel Z97
Memory Slots Four DDR3 DIMM slots supporting up to 32 GB
Up to Dual Channel, 1333-3300 MHz
Video Outputs HDMI (4096x2160 at 24 Hz or 2560x1600 at 60 Hz)
DisplayPort (4096x2160 at 25 Hz or 3840x2160 at 60 Hz)
Mini-DisplayPort (4096x2160 at 24 Hz or 3840x2160 at 60 Hz)
Onboard LAN Intel I218V
Intel I211-AT
Broadcom 802.11ac 2T2R
Onboard Audio Realtek ALC1150 with Crystal Sound 2
Expansion Slots 2 x PCIe 3.0 x16 (x16 or x8/x8)
1 x PCIe 2.0 x4*
4 x PCIe 2.0 x1
Onboard SATA/RAID 6 x SATA 6 Gbps Ports (PCH)*
1 x SATA Express (PCH)*
1 x M.2 PCIe and SATA (PCH)*
1 x SATA Express (ASMedia) with 2x SATA 6 Gbps
2 x SATA 6 Gbps (ASMedia)
*The PCIe x16_3, USB3_E56 and SATAExpress_E1
connectors share the same bandwidth.
*M.2 Socket 3 shares bandwidth with SATAExpress_1
*Use ThunderboltEX II/DUAL card in PCIeX16_3 slot,
configure the bandwidth to x4 mode in BIOS
USB 3.0 4 x USB 3.0 (PCH) [4 rear panel]
6 x USB 3.0 (ASMedia) [2 rear panel, 2 headers]
Onboard 10 x SATA 6 Gbps ports
1 x M.2
2 x SATA Express
2 x USB 3.0 Headers
2 x USB 2.0 Headers
1 x TPM Header
6 x Fan Headers
1 x EZ XMP Switch
1 x Thunderbolt Header
TPU Switch
EPU Switch
Power Button
Reset Button
Clear CMOS Button
MemOK! Button
USB BIOS Flashback Button
DirectKey Header
Front Audio Header
Front Panel Header
Power Connectors 1 x 24-pin ATX
1 x 8-pin CPU
Fan Headers 1 x CPU (4-pin)
1 x CPU_OPT (4-pin)
4 x CHA (4-pin)
IO Panel 4 x USB 2.0
6 x USB 3.0
Wi-Fi GO! Module (802.11ac 2T2R, BT v4)
2 x Ethernet (Intel I218V/I211-AT)
Audio Jacks (Realtek ALC1150)
Warranty Period 3 Years
Product Page Link

Personal preference would put the DirectKey back as a button, but I doubt that many users would care much about it. The complexity of using this storage vs. disabling another feature is a little complex, perhaps too much so. Because storage is still driven (perhaps erroneously) by peak read/write speeds, it cannot be hidden behind a PLX chip (such as the 8608) where the uplink is of fewer lanes. One way to get around this issue might be the PLX8747 chip on the CPU, splitting the 16 CPU lanes into 32 (refer back to our big PLX8747 Z77 review to refresh on how the PLX works here).

With 32 lanes, we can split into four groups of 8. Two groups of 8 can do GPU duties, combining for a single GPU and using a switch to split into two lots of x8 when dual GPUs are required. The other two sets of 8 can be used to supply SATA Express slots, M.2 slots and other controllers. Because there are limits to how many endpoints can be generated via the PLX chip, other ICs (such as the PLX8717, which takes in x8 and can put out x4/x4, or take in x4 and output x4/x2/x2) might be required, which will drive up cost but allow all the ports to be used together. So crazy ideas such as a motherboard with SLI capabilities, four M.2 x2 slots and two PCIe 2.0 x4 slots could be possible. Or given the propensity for one manufacturer to play with LSI chips for more SATA ports, that is another option.

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  • Eidigean - Friday, May 16, 2014 - link

    First off, This is a great review Ian. The in-depth details of shared PCIe lane distribution between the x4 slot, x2 M.2, and x2 SATAe helped me make a decision...

    I'm looking for Thunderbolt 2 and two x4 M.2 SSDs. The only board that seems like it will fit the bill is the GIGABYTE GA-Z97X-UD7 TH. Reason being, it's the only board that provides x8/x4/x4 from the CPU while also providing x4 from the Z97 for the Thunderbolt controller. This will allow for a GPU and two Samsung XP941 M.2 SSDs in a RAID 0.

    An alternative I'm kicking around is the Asus Z79-WS with its PLX switch; allowing x16 for the GPU, two x4 M.2 SSDs in two x8 slots, and the ASUS Thunderbolt 2 controller in the x4 slot from the Z79.

    Ian, could you get your hands on the two Samsung XP941 sticks that Kristian was testing?
  • Eidigean - Friday, May 16, 2014 - link

    The ASUS Z97 lineup would be better if ASUS put a x4 slot in place of the middle or bottom x1 slot and shared 4 lanes from the x8 slot when needed, allowing for x8/x4/x4 in addition to x8/x8. Intel allows for it, and only one vendor (GIGABYTE) is doing it.
  • Eidigean - Friday, May 16, 2014 - link

    There's actually another vendor that *almost* meets my requirements, the ASRock Z97 Extreme6. From their user manual:

    * If M2_1 slot is occupied, PCIE2 slot will run at x8 mode, and PCIE4 slot will run at x4 mode.

    That would allow me to run one XP941 stick in the motherboard's M.2 socket, and the other in the PCIE4 slot. The missing feature is Thunderbolt 2; which is only offered by ASUS and GIGABYTE.
  • Ian Cutress - Friday, May 16, 2014 - link

    Hi Eidigean,
    I have the Z97 Extreme6 in for testing, should have a review (with a single XP941) incoming. I've got some data regarding the impact an x4 M.2 has on GPU performance, stay tuned for that.
  • Taurus229 - Friday, May 16, 2014 - link

    Considering this is a $400.00 board, I feel that no one should have to play musical chairs with Sata inputs! Asus missed the boat here!
  • austinsguitar - Friday, May 16, 2014 - link

    one does not just simply pay 400+ dollars on just a motherboard with thunderbolt 2's.... this is a little bit overkill and stupid to the common consumer/ marketing executive. This premium doesn't make much since....
  • DMCalloway - Friday, May 16, 2014 - link

    Great review! Unfortunately, one of the best selling i7 chips (2600k) isn't in the benchmarks. I do like the progress being made with the UEFI BIOSs. Thanx for the review Ian.
  • EricPraline - Saturday, May 17, 2014 - link

    Many high-end motherboards these days use special audio capacitors for 'better' sound in the audio area of the motherboard. The amount of capacitors used in the audio portion of newer motherboards seems to vary using anywhere from 6 to 14 or more depending on the motherboard. Does using more capacitors for audio roughly correlate with a better sound? Why is there a difference in the number of audio capacitors used among high-end ALC1150-based motherboards, even by the same manufacturer (e.g., Asus)
  • Haravikk - Saturday, May 17, 2014 - link

    I find the selection of SATA ports and the juggling act of connecting them a bit weird; I thought that one of the advantages of SATA Express was that you could still use it as two ordinary SATA ports, only getting the increased speed when you connected a full SATA Express cable? With that in mind I don't see why this really needs so many additional, regular SATA ports anyway; an extra two would be enough for most people, as that gives you either six regular SATA drives, or two SATA Express and two regular SATA. Or they could even have gone for four SATA Express which would be even better as it gives you four to eight ports.

    I dunno, it just feels a bit like an odd in-between standards kind of mixture; since Intel will most likely be pushing to increase PCI lanes on future processors then it just seems like if you need so much connectivity you're still better going for a dual processor motherboard, or waiting a year for more Thunderbolt friendly processors.
  • Laststop311 - Monday, May 19, 2014 - link

    Seems to me Intel needs to stop cheaping out on the pci-e lanes for its mainstream line. Now that sata express needs 4x pci-e 3.0 lanes to function to it's maximum. Asrock Extreme 9 is the only board right now that allows you to connected an SSD directly to the CPU using 4 pci-e 3,0 lanes and surprise those drives function the best. With skylake and Z107 intel really needs to step up its pci-e lane game.

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